Floor panel with sealing means

ABSTRACT

Floor panels and floor elements therefore are made of sheet-shaped cores which are formed with sealing means for preventing or counteracting changes in the properties of the floor panels caused by moisture.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. application Ser. No.13/011,398, filed on Jan. 21, 2011, which is a continuation of U.S.application Ser. No. 10/205,395, filed on Jul. 26, 2002, now U.S. Pat.No. 8,028,486, which claims the benefit of U.S. Provisional ApplicationNo. 60/313,462, filed on Aug. 21, 2001 and the benefit of SwedishApplication No. 0102620-2, filed on Jul. 27, 2001. The entire contentsof each of U.S. application Ser. No. 13/011,398, U.S. application Ser.No. 10/205,395, U.S. Provisional Application No. 60/313,462, and SwedishApplication No. 0102620-2 are hereby incorporated herein by reference.

BACKGROUND

1. Technical Field

The invention relates generally to the field of moisture-proof jointsystems for floor panels. The invention relates to a moisture-prooflocking system for floor panels which can be joined mechanically; floorpanels provided with such a locking system; semi-manufactures forproducing such floor panels; and methods for producing suchsemi-manufactures and floor panels. Exemplary embodiments can be used inmechanical locking systems integrated with the floor panel, forinstance, of the type described and shown in WO9426999, WO9966151,WO9966152, SE0100100-7 and SE0100101-5 (owner Valinge Aluminium AB) butis also usable in optional joint systems which can be used for joiningof floors.

More specifically, the invention relates to moisture-proof lockingsystems for floors of the type having a core and a decorative surfacelayer on the upper side of the core.

2. Field of Application of the Invention

Exemplary embodiments of the present invention can be used for use forfloating floors, which are made of floor panels which on the one handare joined mechanically with a joint system which is integrated with thefloor panel, i.e., factory mounted, and, on the other hand, are made upof one or more preferably moisture-proof upper layers of a decorativelaminate or decorative plastic material, an intermediate core offiberboard-based material or plastic material and preferably a lowerbalancing layer on the rear side of the core. The following descriptionof the state of the art, problems associated with known systems and theobjects and features of the invention will therefore, as anon-restricting example, focus first of all on this field of applicationand, in particular, on laminate flooring made of rectangular floorpanels, intended to be mechanically joined on both long sides and shortsides. However, it should be noted that the invention can be used inoptional floor panels with optional joint systems where the floor panelshave a core and are given their final shape by cutting. The inventioncan thus also be applicable to homogeneous wooden flooring and woodenflooring having two or more layers of wood or fiberboard-based materialand a decorative surface layer of wood. Thus, the invention may beapplied to floor panels comprising any wood fiber-based material, suchas solid wood, plywood, particle board, fiberboard, MDF, HDF etc.Further, the discussion related to moisture penetrating into the jointsystem from the front side of the floor panel is also applicable to thecase of preventing moisture from penetrating into the joint system fromthe rear side of a floor panel.

BACKGROUND OF THE INVENTION

In the discussion of the state of the art that follows, reference ismade to certain structures and/or methods. However, the followingreferences should not be construed as an admission that these structuresand/or methods constitute prior art. Applicant expressly reserves theright to demonstrate that such structures and/or methods do not qualifyas prior art against the present invention.

Laminate flooring is usually composed of a core of a 6-9 mm thickfiberboard, a 0.2-0.8 mm thick upper decorative surface layer oflaminate and a 0.1-0.6 mm thick lower balancing layer of laminate,plastic, paper and like material. The surface layer provides appearanceand durability to the floor panels. The core provides stability, and thebalancing layer keeps the panel plane when the relative humidity (RH)varies during the year. The RH can vary between 15% in winter and 90% insummer. The floor panels are usually laid floating, i.e. without gluing,on an existing subfloor which need not be entirely smooth or plane. Anyirregularities are eliminated by means of underlay material in the formof, for instance, board or foam which is arranged between the floorpanels and the subfloor. Traditional hard floor panels in floatingflooring of this type are as a rule joined with the aid of gluedtongue-and-groove joints (i.e. joints with a tongue on one floor paneland a tongue groove in an adjoining floor panel) on long side and shortside. When laying, the panels are joined horizontally, a projectingtongue along the joint edge of one panel being inserted into a tonguegroove along a joint edge of an adjoining panel. The same method isapplied to long side as well as short side.

In addition to such traditional floors, which are joined by means ofglued tongue-and-groove joints, floor panels have recently beendeveloped which do not require the use of glue and instead are joinedmechanically by means of so-called mechanical joint systems. Thesesystems contain locking means which lock the panels horizontally andvertically. The mechanical joint systems can be made by machining thecore of a panel. Alternatively, parts of the locking system can be madeof a separate material which is integrated with the floor panel, i.e.joined with the floor panel even in connection with the productionthereof.

An advantage of floating floors with mechanical joint systems is thatthey can be easily and rapidly laid by different combinations of inwardangling and snapping-in. They can also easily be taken up again and bereused in another place. A further advantage of the mechanical jointsystems is that the edge portions of the floor panels can be made ofmaterials which need not have good gluing properties. The most commoncore material is wood in parquet flooring and in laminate flooringfiberboard of high density and good stability usually referred to asHDF—high density fiberboard. Sometimes MDF—medium density fiberboard—isused as core.

Laminate flooring and also many other floorings with a surface layer ofplastic, wood, veneer, cork and the like are produced by a surface layerand a balancing layer being applied to a core material. This applicationcan take place by gluing of a previously manufactured decorative layer,for instance when the fiberboard is provided with a decorative highpressure laminate which has been made in a separate operation where aplurality of impregnated sheets of paper are compressed under highpressure and at a high temperature. The currently most common method inproducing laminate flooring, however, is direct laminating which isbased on a more modern principle where both production of the decorativelaminate layer and the attachment to the fiberboard take place in oneand the same step of production. Impregnated sheets of paper are applieddirectly to the board and are compressed under pressure and heat withoutgluing.

In addition to these two methods, a number of other methods forproviding the core with a surface layer can be used. A decorativepattern can be printed on the surface of the core, which is then, forinstance, coated with a wear layer. The core can also be provided with asurface layer of wood, veneer, decorative paper or plastic film, andthese materials can then be coated with a wear layer.

The above methods can result in a floorboard element in the form of alarge panel which is then sawn into, for instance, some ten floorboards,which are then machined to floor panels. In some cases, the abovemethods may result in completed floorboards and then sawing is notnecessary before machining to completed floor panels is carried out.Production of individual floorboards usually takes place when the boardshave a surface layer of wood or veneer.

The above floorboards can be individually machined along their edges tofloor panels. Edge machining can be carried out in advanced millingmachines where the floorboard is exactly positioned between one or morechains and bands mounted so that it can be moved at high speed and withgreat accuracy past a number of milling motors which are provided withdiamond cutting tools or metal cutting tools which process the edge ofthe floorboard. By using a plurality of milling motors which operate atdifferent angles, advanced joint geometries can be formed at speedsexceeding 100 m/min and with an accuracy of (0.02 mm.

DEFINITION OF SOME TERMS

In the following text, the visible surface of the completed, mountedfloor panel is called “front side”, while the opposite side of the floorpanel facing the subfloor is called “rear side”.

The sheet-shaped starting material that is used is called a “core”. By“fiberboard core” is meant a core material containing wood fibers suchas homogeneous wood, MDF, HDF, particle board, flake board, plywood andthe like. When the core has been coated with a surface layer closest tothe front side and preferably also a balancing layer closest to the rearside, it forms a semi-manufacture, which is related to as a “floorboard”or a “floor element”.

A “floorboard” is generally of the same size as the floor panel which isto be produced from the floorboard. Thus, the floorboard is generallyformed into a floor panel.

The “floor element”, on the other hand, is typically so large that atleast two floor panels may be produced from it. Thus, the floor elementis usually divided into several floor boards, which are subsequentlyformed into floor panels.

Hence, when the edges of the floorboards have been machined so as togive the floorboards their final shape, including the joint system, theyare related to as “floor panels”. By “surface layer” are meant alllayers that are applied to the core closest to the front side and thatcover preferably the entire front side of the floorboard. “Decorativelayer” relates to layers that are intended to give the floor itsdecorative appearance. “Wear layer” relates to layers that are above allintended to improve the durability of the front side.

The outer parts of the floor panel at the edge of the floor panelbetween the front side and the rear side are related to as “joint edge”.As a rule the joint edge has several “joint surfaces” that can bevertical, horizontal, angled, rounded, beveled, etc. These jointsurfaces are to be found on different materials included in the floorpanel and the joint system, e.g., laminate, fiberboard, wood, plywood,plastic, metal (especially aluminum) or sealing material. “Joint edgeportion” relates to joint edge and part of the floor panel portionsclosest to the joint edge.

By “joint” or “joint system” are meant cooperating connecting meanswhich join the floor panels vertically and/or horizontally.

Laminate flooring and also wooden flooring are often laid in kitchens,hallways and public rooms where they are continually exposed to water,for instance in the form of people walking on the floor with wet shoesand when cleaning the floor with water and the like. In recent years,laminate flooring is being used in bathrooms as well. Laminate andwooden flooring are being sold all over the world and installed in humidclimates where the relative humidity may exceed 90%.

When water penetrates into a material or when evaporated or condensedwater is to be found on or in materials, it is generally related to as“moisture”.

By “moisture-proof material” are generally meant materials which to alimited extent absorb moisture or materials that are not damaged bymoisture.

Moisture in Floors

When a laminate floor with a fiberboard-based core is exposed tomoisture to a limited extent in the rooms mentioned above, the moisturecan penetrate, via the joint between neighboring floor panels, into theupper parts of the joint system closest to the front side and thuspenetrate into the core and its wood fibers. If the amount of moisturesupplied is small, the water usually evaporates after some time, but, asa result, a permanent swelling of the joint edge portion, rising of theedge of the upper joint edge portion and cracks in the surface layer mayarise in particular if the quality of the core is not high and if thelaminate is thin. Rising of the edge also causes great wear on thesurface layer round the joint edges. In a wooden floor, the joint edgesmay also swell at a high relative humidity and cause damage to the jointedges.

If the supply of moisture is extensive or if it takes place regularlyfor a long time, moisture may also penetrate through the entire jointsystem and into the subfloor and cause considerable damage such as inthe form of mold. This may take place even if the floor panel is made ofa moisture-proof core since this moisture-proof core can merelycounteract swelling of the joint edge portions or prevent moisture fromspreading into the core. The moisture-proof core may not preventmoisture from spreading through the joint system and into the subfloor.This moisture migration through the joint system is reinforced if thegeometry of the mechanical joint contains many joint surfaces on a floorpanel, which do not have contact with corresponding joint surfaces onthe neighboring floor panel. Such a geometric design facilitates, forinstance, manufacture and facilitates displacements of a floor panel inits locked position along the joint edge of a neighboring floor panel,but such a geometric form may not be advantageous in counteracting thepossibility of moisture penetrating through the joint system.

A common misconception is that mechanical joint systems are moresensitive to moisture than traditional joint systems with glue sinceglue is considered to prevent moisture from penetrating into the jointsystem. Glued floors with environment-friendly water-based glue systems,however, cannot prevent moisture from penetrating into the joint system.One reason is that glue is found only in parts of the joint system.Another reason is that moisture that comes into contact with the gluelayer can dissolve the glue joint. The moisture penetrates through thejoint system and the panels come loose in the joint.

Laminate floors and wooden floors could take a considerably greatermarket share, especially from plastic floors and tiled floors, if theycould resist in a better way the effect of high relative humidity and ofwater on the surface.

PRIOR-ART TECHNIQUE AND PROBLEMS THEREOF

When a laminate floor is exposed to water on its surface, amoisture-proof surface layer will counteract that moisture penetratesthrough the surface and into the core. The limited amount of moisturepenetrating through the surface layer and into the core may not causeany damage. However, in the joints, moisture can penetrate between theupper joint edges of neighboring floor panels, and as the moisturepasses the moisture-proof surface layer and reaches the significantlymore moisture-sensitive core, the moisture can spread into the core andat the same time continue towards the rear side of the floor panel. Ifthe core contains wood fibers, these can swell. As a result, thethickness of the floor panel within the joint edge portion increases andthe surface layer rises. This vertical swelling in turn causes damage tothe floor. If additional moisture is supplied, the moisture can spreaddownwards to the rear side until it has passed the joint system andreaches the underlay board and the subfloor. This may cause even greaterdamage.

Various methods have been used to counteract these problems. Attemptshave been made to prevent moisture from penetrating into the floor panelfrom the joint edge by coating the joint surfaces with amoisture-sealing material, for instance wax or silicone. This type ofsolution is described in, inter alia, WO9426999 (Valinge Aluminium AB)and EP0903451 (Unilin Beheer B. V.). One has tried to counteractmoisture migration from the front side to the rear side of the floorpanels along the joint by inserting elastic sealing means betweenneighboring floor panels. Such solutions are disclosed in, inter alia,WO9747834 (Unilin Beheer B. V.).

Thus use has been made of several methods in order to improve in variousways the possibilities of the joint systems withstanding the effect ofwater and moisture.

One common method is to make the core of the floor panel of a HDF panelof high quality as regards, e.g., density and protection againstmoisture. The core's protection against moisture can also be improved byadding specific binders, in many cases in combination with use ofspecial wood fibers when making the core. This method can significantlyreduce, but not entirely eliminate, swelling as moisture penetrates. Themain disadvantage of this method is the cost. The entire floor panelwill have the same high quality although these specific properties areonly utilized in a limited part of the floor panel in connection withthe joint edge. Another disadvantage is that this method does not affordprotection against moisture migration through the joint system from thefront side to the rear side of the floor.

It is also known that it is possible to counteract penetration ofmoisture into the core of the floor panels by spraying on, or otherwiseapplying to, the joint edges special chemicals which impregnate orreinforce the wood fibers in the joint system. This application ofchemicals takes place after the joint by machining has been given isfinal shape and geometric form. The impregnation can take placeimmediately in connection with the machining of the edges of the floorpanels since it is desirable to use the condition that in this step ofproduction the panel is held in the correct position by drive chains orbelts in the machining equipment.

The impregnating materials can be applied in the joint system usingdifferent methods which can involve application by spraying, rolling,spreading and the like. A common impregnating material is melted wax andliquids of different kinds such as oils, polyurethane-based impregnatingagents and a number of other chemicals which all contribute tocounteracting penetration of moisture from the joint edge into the coreso as to reduce the risk of swelling as moisture penetrates between theupper joint edges.

Methods of application can be complicated, expensive and give anunsatisfactory result. It can be particularly difficult to providemoisture-proof corners. If application by spraying on a moving floorpanel, for instance, starts too late, part of the edge closest to thecorner will have no impregnation. If spraying is terminated too late,impregnating liquid will reach the open air, and this will causeundesirable smearing of equipment and also spreading of undesirablesolvents or impregnating materials in the air and the room whereproduction takes place. It can also be difficult to impregnate the coreat the joint edge immediately under the surface layer withoutsimultaneously causing smearing of the surface of the floor panelclosest to the joint edge. It is also difficult to obtain deep and evenimpregnation in the areas immediately under the surface layer which aremost exposed to moisture and swelling. Everything can be made worse bythe fact that machining and thus subsequent impregnation take place atvery high speeds and with the surface layer of the floor panels facingdownwards. Further disadvantages are that the impregnation, especiallyif it is water-based and environment-friendly, may cause fibers to swellor a layer of solidified impregnating agent to settle in the jointsystem in such manner that the geometry of the joint is changed in anuncontrolled manner.

Besides the above methods do not result in a reliable seal againstmoisture migration from the front side of the floor panels along thejoint surfaces down to the rear side of the floor panels. Nor can theysolve the problem of swelling of upper joint edge portions in woodenfloors.

It is also known that is possible to use core materials of plastic whichdo not swell and do not absorb moisture. This can give a seal againstmoisture migration horizontally away from the joint between two joinedfloor panels. However, plastic is disadvantageous since panels ofplastic material are considerably more expensive than fiberboard andsince it is difficult to glue or directly laminate a decorative surfacelayer on a panel of plastic material. Moreover machining of plastic ismuch more difficult than machining of fiberboard-based material formaking the connecting means of the floor panels along all four edges. Anexample of a floor panel having a plastic core is provided inEP1045083A1. An example of a floor panel having connecting means made ofplastic materials is provided in U.S. Pat. No. 6,101,778.

The above-mentioned publication WO9426999 (Valinge Aluminium AB)discloses a system for counteracting moisture penetration into the floorpanels from the joint edges and for counteracting moisture migrationfrom the front side of the floor panels to their rear side. Thispublication suggests the use of silicone or some other sealing compound,a rubber strip or some other sealing device which is applied in thejoint system before installation. The system according to WO9426999(Valinge Aluminium AB), i.e., sealing against moisture using a sealingcompound or a sealing device, which is applied in the joint inconnection with manufacturing, also has drawbacks. The drawbacks aresimilar to those associated with edge impregnation by spraying orspreading. It is also difficult to handle panels with a smeary sealingcompound. The properties of the sealing compound can also change incourse of time. If the sealing compound is applied in connection withlaying, laying will be difficult and expensive.

One possibility of establishing a seal against penetration of moistureis to insert, in connection with laying, a sealing device in the form ofe.g. a sealing strip of rubber into the joint. Also this method isdifficult and expensive. When the sealing means is applied in the jointin connection with manufacture, it is not known how the sealing means isto be designed for optimal functions, how the application should takeplace in a rational manner and how the corners should be designed sothat the seal can function along the joint edge of the entire floorpanel both on the long sides and on the short sides. The above-mentionedpublication WO9747834 (Unilin Beheer B. V.) shows in FIG. 10 how sealingmeans have been applied in a visible manner between the upper jointedges, so that a narrow gap is to be seen between the neighboring floorpanels.

The use of inserted elastic sealing means in joints is known also inconnection with the joining of story-high wall elements. This is shownin for instance GB2117813 (Ostrovsky) disclosing a joint system, which,however, is not suitable for floor panels that are to be laid withoutgreat visible joint gaps.

Furthermore, it is known to apply a sealing paste or a water resistantglue in a joint between the floor panels as is shown in EP 0665347A1.However, such a procedure would require the seal to be applied at thetime the panels are installed. Furthermore it would be associated withmost of the drawbacks inherent in floor panels which are connected bymeans of glue.

It is also known (according to WO 9966152, Valinge Aluminium AB) that itis possible to provide the edge of the core on the long side or theshort side with separate materials which are attached to the core andwhich are then machined to achieve specific functions in the lockingsystem, such as strength, protection against moisture or flexibility.However, it is not known how these materials are to be applied andformed in order to solve the moisture problems described above in anoptimal manner.

A specific problem, which is related to moisture penetration in floorpanels from the joint edges, arises in connection with wooden floorpanels which have several wooden layers with different directions offibers since wood swells to a greater extent transversely of thedirection of fibers than along the direction of fibers. This means thatin a wooden floor, which has a surface layer with its direction offibers in the longitudinal direction of the floor panel and a corehaving a different direction of fibers, for instance transversely of thefloor panel, and which is installed in an environment which is moist orhas a high relative humidity, the surface layer will swell to a greaterextent in the transverse direction of the floor panel than does thecore. As a result, the upper joint edge portions and especially theparts closest to the joint surface will swell and expand parallel withthe surface of the floor panel and move the floor panels apart whereasthe joint system made in the core largely retains its form. This maycause damage, for instance, by the decorative layer (surface layer)being compressed, the joint system breaking or the locking function ofthe locking system being wholly or partly lost.

It may therefore be established that moisture problems in connectionwith joined floor panels are associated with vertical and horizontalswelling of the joint edge portions by moisture penetration through thejoint system.

Summing up, it can be said that as regards the providing of a sealagainst moisture migration in the floor panels from the joint edges,there are a plurality of known methods, none of which provides a resultwhich is satisfactory as regards quality as well as cost. As regardssealing against moisture migration along the joint from the front sideto the rear side of the floor panels, known solutions do not allow anintegrated design where the panel even in connection with manufacture isprovided with a seal that counteracts such moisture migration.

SUMMARY OF THE INVENTION

The invention is based on the understanding that several types of sealsmay be involved for a moisture-proof locking system for floor panelswhich can be joined together, viz. “material seal” which counteractsswelling of joint edges, “material seal” and “joint seal” whichcounteract swelling and moisture penetration through the joint system,“compensation seal” which compensates for swelling and shrinkage ofjoint edges.

By “material seal” is meant a seal which prevents or counteractsspreading of moisture from the joint edge of a floor panel into thefloor panel. By “joint seal” is meant a seal which prevents orcounteracts migration of moisture through the joint along the jointsurfaces. By “compensation seal” is meant a seal which adjusts tomaterial movements caused by moisture in a floor panel (swelling andshrinkage) owing to changes of the moisture content, for instance bychanges in relative humidity in the ambient air, and which counteractsstress under compression and the arising of a visible gap between theupper joint edges of neighboring floor panels owing to such materialmovements caused by moisture.

As is evident from that stated above, the known solutions to problemscaused by the moisture in connection with floor panels and floormaterials are not quite satisfactory. Some of the solutions areinsufficient as regards the intended effect, others have deficiencieswhich cause difficulties in connection with manufacture or laying,whereas others are unsatisfactory from the viewpoint of cost.

Therefore an object of the present invention is to eliminate orsignificantly reduce one or more of the remaining problems associatedwith moisture sealing in connection with manufacture and use of floorpanels. A further object of the invention is to provide a rational andcost-efficient manufacturing method for manufacturing floor panel cores,floorboard elements, floorboards and floor panels.

These and other objects are achieved by floor panels, floors andmanufacturing methods having the features that are stated in theindependent claims. The dependent claims and the following descriptiondefine embodiments of the invention.

The invention is especially suited for use in floor panels withmechanical locking systems and in floor panels which are made from boardelements which are divided into a plurality of boards before machining.However the invention can also be used for floors with a joint systemthat is glued and for floor panels that are produced directly asseparate floorboards for machining to floor panels and which are thusnot manufactured by dividing large board elements before subsequentmachining of the individual floorboards.

Thus, according to a first aspect of the invention, there is provided afloor panel, having a body comprising a wood fiber-based core, in whichfloor panel at least at two opposite parallel joint edge portions haveconnecting means for mechanical joining of the floor panel in thehorizontal direction with similar floor panels, the connecting meanshaving active locking surfaces for cooperation with corresponding activelocking surfaces of neighboring floor panels after the floor panel hasbeen joined therewith. The active locking surfaces wholly or partly aremade of an elastically deformable material, other than that of the bodyof the floor panel.

According to a second aspect of the invention, there is provided asystem for forming a joint between two adjoining edges of floor panels,which have a core and a surface layer applied to the upper side of thecore and consisting of at least one layer, and which at their adjoiningjoint edge portions have connecting means for joining the floor panelswith each other in the vertical direction and whose upper adjoiningjoint edges meet in a vertical joint plane. At least one of the oppositejoint edge portions of the floor panels, when the floor panels arejoined together, has a joint seal for counteracting penetration ofmoisture along the joint surfaces of the joint edges between neighboringfloor panels, and that this joint seal is made of an elastic sealingmaterial and secured in at least one of the floor panels, formed inconnection with the forming of the joint edges (82, 83) of the floorpanels, and compressed when neighboring floor panels are joinedtogether.

According to a third aspect of the invention, there is provided a floorpanel having a core and a surface layer applied to the upper side of thecore and consisting of at least one layer, the floor panel at oppositejoint edge portions having connecting means for joining the floor panelwith similar floor panels in the vertical direction, so that joinedfloor panels have upper joint edges which meet in a vertical jointplane. At least one of the opposite joint edge portions of the floorpanels has a joint seal for counteracting penetration of moisture alongthe joint surfaces of the joint edges between neighboring floor panels,and that this joint seal is made of an elastic sealing material andsecured in the floor panel, formed in connection with the forming of thejoint edges (82, 83) of the floor panels and is elastically deformedwhen the floor panel is joined with a similar floor panel.

Thus, according to the first, second and third aspects of the invention,the core can be provided with inserted and fixedly secured elasticallydeformable materials, which may act as a sealing means and/or ascompensation means for swelling or shrinking of the floor panels. Theelastically deformable materials are applied in portions that will laterwill be machined for making the connecting means of the completed floorpanel. The elastically deformable material will thus be machinedsimultaneously as or in connection with the machining of the remainingparts of the joint system. As a result, the elastically deformablematerial can be made into accurately positioned and accuratelydimensioned seals for forming the above-mentioned joint seals orcompensation means.

According to a fourth aspect of the invention, there is provided amethod of making a core which is intended for production of floor boardsor floor elements to be divided into floor boards which in turn areintended for cutting to floor panels with opposite joint edge portions,said core being made of a sheet-shaped material, especially asheet-shaped wood fiber-based material. The sheet-shaped material withinband-shaped areas, from which the connecting means for vertical joiningof the floor panels to be are intended to be formed, is provided withgrooves extending from a surface of the sheet-shaped material, and thatan elastic sealing material is inserted in said grooves.

According to a fifth aspect of the invention, there is provided a methodfor use in manufacturing a floor panel, the method comprising the stepsdescribed above in connection with the fourth aspect of the invention.The elastic sealing material is formed into a joint seal in connectionwith the forming of the connecting means.

By suitable methods, such as sawing or milling, the core can, beforeapplication of the surface layer (for instance a decorative surfacelayer), be pretreated so that, for instance, one or more grooves areformed in the surface in the areas where edge machining of the jointsystem will later take place. Subsequently, a suitable sealing materialis applied in the groove, suitably by impregnation or extrusion or anyother suitable method. The sealing material may form a material sealand/or may have the property of changing into a solid, moisture-proofand elastically deformable material which could be formed to a jointseal. The surface layer can then be applied to the surface of the coreover the groove with the sealing material. According to this aspect ofthe invention, the sealing material can also be applied in a similar wayafter the application of the surface layer. The groove is then made inthe floor element or the floorboard in the surface layer and in thecore, or merely in the core of the floorboard. When the floor element issawn up in floorboards, the edges will contain the sealing material. Ifthe sealing material is applied in a groove or a machined edge part ofthe floorboard it is preferred that a reference surface is machined inconnection with the application of the sealing material. This referencesurface could be an outer portion of the edge of the floorboard. Thefinal machining of the locking system and the joint sealing could thenbe made in a second production step, where the reference surface couldbe used to position the floorboard in relation to the machining tools.With this method it is possible to position sealing material with atolerance of about 0.01 mm in relation to the joint surfaces, and thesurface of the floor panel. It is possible to position and form a jointsealing in the core and in the lower part of a 0.1-0.5 mm thick surfacelayer. The joint sealing will protect the wood fiber core and preventmoisture from penetrating trough the locking system. This method makesit possible to apply and form a seal in all types of laminate floorsthat could be produced with the sealing material. It is obvious that themethod could be used for thicker surfaces of, for instance, 1-3 mmplastic and linoleum surfaces. Such a sealing will not be visible fromthe surface and it will protect the wood fiber core under the moistureproof surface layer. If the sealing material is flexible, it may alsoprevent moisture from penetrating trough the locking system.

To form a joint sealing it is possible, in principle, to use any knownsealing material, which can be applied in liquid form or in semi-liquidform by extrusion, such as foam or the like, and which after applicationare formable, elastically deformable and moisture-proof. It is anadvantage if the sealing materials have properties which allow adhesionto the core. Such adhesiveness, however, is not necessary since thesealing material can also be attached mechanically in, for instance,undercut grooves.

The subsequent machining in the production of the floor panels iscarried out in such manner that the sealing material is only partlyremoved or reshaped. For instance, the sealing material can be formed bycutting into an elastically deformable joint seal which will be exactlypositioned along the entire long side and the entire short side and inthe corners and also exactly positioned in relation to the surfacelayer.

The joint seal and especially its active part, which provides themoisture seal, can be formed with an optional outer geometry by cuttingwhich can be made with very narrow tolerances in connection with therest of the joint system being formed.

If the joint system between the decorative layer and the joint seal alsohas a material seal, the result will be a floor with floor panels whichall have moisture-proof joints on the long sides and the short sides andin the corners. If the floor is also provided with moisture-proofbaseboards made of, e.g., plastic material which in connection with thefloor have a suitable sealing material or sealing strip, the floor willbe quite moisture-proof in all joints and along the walls.

The material seal between the surface layer and the joint seal can, inaddition to the above-described impregnation, be provided in manydifferent ways, for instance:

The core can be made of a moisture-proof material. In a direct-laminatedfloor, the upper part of the core can immediately under the decorativelayer be impregnated, e.g., according to what is described below.Impregnating material can also be applied in the grooves of the corewhere also the joint seal is applied. In a floor of high pressurelaminate, the laminate's reinforcement layer of phenol-impregnated kraftpaper under the decorative layer can constitute a material seal. Anotheralternative is that a moisture-proof plastic layer is applied betweenthe core and the decorative surface layer in the entire panel.

In the same way as the joint seal is applied, also materials with otherproperties, for instance non-compressible materials, can be applied inorder to protect the joint edge and form a material seal.

The material seal can consist of one or more materials which cover theentire core surface and which are also resilient and sound-reducing. Theadvantage is that it is possible to obtain, at the same cost, a moistureseal, sound reduction and a softer floor. Parts of the joint seal mayalso constitute a material seal. Finally, the entire joint seal, orparts thereof, can also constitute a material seal. This means that thejoint seal may also serve as a material seal with or withoutimpregnation of the core.

As is evident from that stated above, this aspect of the invention issuitable for core materials which are wood fiber-based, e.g.,fiberboard-based, but also for moisture-proof core materials, such asplastic and various combinations of plastic and fiberboard-basedmaterials.

As non-limiting examples of materials that can be used to provide ajoint seal, mention can be made of acrylic plastic-based materials,elastomers of synthetic rubber, urethane rubber, silicone rubber or thelike, or polyurethane-based hot-melt adhesive.

In one embodiment, the floor panels may have a mechanical joint systemwhich for a long time and during swelling and shrinkage of the floorpanels holds together the joint edge with the sealing material in closecontact with another sealing means or with the other joint edge. Themethod and the system may also function in a traditionally gluedtongue-and-groove joint, but it is considerably more expensive and moredifficult to provide a tight joint than with a mechanical joint system.

In connection with laying, it is possible to add glue, sealing materialand the like to the above-described joint system for the purpose of, forinstance, additionally reinforcing the strength or moisture resistanceof the joint in parts of the floor or in the entire floor.

Within the scope of the invention, long sides and short sides can beformed in various ways. The reason may be that the connecting methodduring laying can be different at long sides and short sides. Forinstance, the long side can be locked by inward angling and the shortside by snapping-in, and this may necessitate different materialproperties, joint geometries and seal geometries, where one side isoptimized for inward angling and the other for snapping-in. Anotherreason is that each square meter of floor contains considerably morelong side joint than short side joint if the panels are elongate. Anoptimization of the material cost can give different joint designs.

Impregnation and edge reinforcement of the core in certain areas beforeapplication of surface layer and balancing layer can also be used on therear side in order to, for instance, reinforce that part where the lowerparts of the joint system are formed. This can be used, for instance, tomake a strong and flexible strip or lower lip and a strong lookingelement when the strip or the lower lip is formed integrally with thecore. If, for instance, the strip is made of a material other than thatof the core, for instance aluminum, impregnation from the rear side canbe used to reinforce critical parts, where the strip is secured or wherethe panel cooperates with the locking element.

The above described manufacturing methods can also be used to produce amechanical joint system, which contains elastic locking means. Theseelastic locking means can be pressed together as adjoining upper jointedges swell and can expand as they shrink. In this way, the horizontalswelling problems and the arising of visible gaps in a dry floor can becounteracted. Since this swelling problem is mainly related to the longside, the corners are not involved in this respect. The elasticallydeformable material can therefore also be mechanically applied in solidform in the groove for instance by snapping-in or pressing-in intoundercut grooves of by gluing to the edge of the groove. Thus theseelastic locking means will serve as an “elastic compensation seal”.

The above-described manufacturing method of providing a partial materialseal in predetermined areas in a core can also be used in connectionwith manufacture of the sheet-shaped core. Impregnating material is thenapplied either in the compound of wood fiber and binder which is formedto a core or in connection with the core getting its final shape in themanufacturing process.

According to a sixth aspect of the invention, there is provided arectangular floor panel having long sides, short sides, a core and asurface layer applied to the upper side of the core and comprising atleast one decorative layer, the floor panel adjacent to opposite jointedge portions having connecting means for joining the floor panel withsimilar floor panels in the vertical direction and in the horizontaldirection along the long sides and short sides. The floor panel seenfrom the front side, adjacent to joint edge portions at least at onelong side and one short side has a wear layer, a decorative layerapplied under the wear layer, a portion located under the decorativelayer and constituting a material seal for counteracting penetration ofmoisture from the joint edge of the floor panel into the core and anelastically deformable joint seal which is located under the materialseal and is fixedly secured in the floor panel and which, when the floorpanel is joined with a similar floor panel, counteracts penetration ofmoisture along the joint surfaces of the joint edges between theneighboring floor panels, and that at least one of the verticalconnecting means is made from the core.

According to a seventh aspect of the invention, there is provided afloorboard for use in forming at least two floor panels, the floorboardcomprising a wood fiber-based core and a surface layer that is attachedto a surface of the core. A groove is provided in the surface of thecore and/or in the surface layer, said groove being arranged in aportion of the board where a mechanical locking system is to be formed,and said groove being provided with an elastically deformable materialand/or an impregnation agent. The elastically deformable material may beformed into the joint seal described above at least partly in connectionwith the forming of the connecting means.

According to an eight aspect of the invention, there is provided afloorboard for use in forming a floor panel, the floorboard comprising awood fiber-based core and a surface layer that is attached to a surfaceof the core. A groove is provided in an upper edge portion of thefloorboard, where a mechanical locking system is to be formed, saidgroove being provided with an elastically deformable material and/or animpregnation agent.

BRIEF DESCRIPTION OF THE DRAWINGS

The objects and advantages of the invention will become apparent fromthe following detailed description of preferred embodiments thereof inconnection with the accompanying drawings in which like numeralsdesignate like elements and in which:

FIGS. 1 a-d illustrate different steps in the production of a floorpanel.

FIGS. 2 a-e show the composition of a laminate floor with a surface ofhigh pressure laminate and direct laminate.

FIGS. 3 a-c illustrate examples of different mechanical joint systemsand moisture migration.

FIGS. 4 a-d illustrate impregnation of an edge according to prior-arttechnique.

FIGS. 5 a-c show impregnation to form a material seal according to theinvention.

FIGS. 6 a-c show impregnation of upper joint edges according to thepresent invention.

FIGS. 7 a-d illustrate an embodiment of a material seal according to theinvention.

FIGS. 8 a-e illustrate the making of a joint seal in a mechanical jointsystem according to the invention.

FIGS. 9 a-d illustrate the making of a mechanical joint system withmaterial seal and joint seal as well as edge reinforcement of parts ofthe joint system according to the invention.

FIGS. 10 a-c illustrate compression of a joint seal according to theinvention.

FIGS. 11 a-f illustrate alternative embodiments of material and jointseals according to the invention.

FIGS. 12 a-b illustrate alternative embodiments of material and jointseals according to the invention.

FIGS. 13 a-c illustrate floor panels with a joint seal on two sidesaccording to the invention.

FIGS. 14 a-e illustrate mechanical locking systems, FIG. 14 aillustrating prior-art technique and FIGS. 14 b-e illustratingmechanical locking systems with a compensation seal in the form of anelastic locking means according to the invention.

FIGS. 15 a-e illustrate an embodiment of the invention.

FIGS. 16 a-f illustrate a joint system which is formed according to theinvention and has high strength.

FIGS. 17 a-d illustrate sealing of corner portions of neighboring floorpanels.

DESCRIPTION OF PREFERRED EMBODIMENTS

FIGS. 1 a-d illustrate in four steps the manufacture of a floor panel.FIG. 1 a shows the three main components surface layer 31, core 30 andbalancing layer 32. FIG. 1 b shows a floor element 3, where the surfacelayer and the balancing layer have been applied to the core. FIG. 1 cshows how floorboards 2 are made by dividing the floor element. FIG. 1 dshows how the floorboard 2 after edge machining obtains its final shapeand becomes a completed floor panel 1 with a joint system 7, 7′ on thelong sides 4 a, 4 b, which joint system in this case is mechanical.

FIG. 2 a shows manufacture of high pressure laminate. A wear layer 34 ofa transparent material having a high wearing strength is impregnatedwith melamine with addition of aluminum oxide. A decorative layer 35 ofpaper impregnated with melamine is placed under this layer 34. One ormore layers of reinforcement layers 36 a, 36 b made of paper core andimpregnated with phenol are placed under the decorative layer 35, andthe entire packet is placed in a press in which it is caused to cureunder pressure and heat to a surface layer 31 of high pressure laminatehaving a thickness of about 0.5-0.8 mm.

FIG. 2 c shows how the surface layer 31 and a balancing layer 32 arethen glued to a core 30 so as to form a board element 3.

FIGS. 2 d and 2 e illustrate direct lamination. A wear layer 34 in theform of an overlay and a decorative layer 35 of decoration paper areplaced directly on a core 30, after which all three parts and, also arear balancing layer 32 are placed in a press where they are caused tocure under heat and pressure to a board element 3 with a decorativesurface layer 31 having a thickness of about 0.2 mm.

FIGS. 3 a-c illustrate prior-art mechanical joint systems and howmoisture, according to studies made by the inventors, affects the jointsystems. In FIG. 3 a, the floor panel 1 consists of a direct-laminatedsurface layer 31, a core 30 of fiberboard-based material (HDF) and abalancing layer 32. The vertical locking means which locks the panels 1and 1′ in the D1 direction, consists of a tongue groove 9 and a tongue10. The horizontal locking means which locks the panels parallel withthe surface layer 31 in the D2 direction consists of a strip 6 having alocking element 8 which cooperates with a locking groove 12. The stripis made by machining of the core 30 of the floor panel and is thereforein this embodiment of the invention formed integrally with the core 30.Dashed arrows MPM indicate how moisture can penetrate from the jointedge into the core 30 as moisture penetrates into the joint system fromthe front side or upper side of the floor.

FIG. 3 b illustrates an embodiment where both the vertical and thehorizontal locking means are formed as a tongue groove 9 with a lockinggroove 12 and a tongue 10 with a locking element 8. The dashed arrow MPJillustrates how moisture can penetrate through the parts of the lockingsystem.

In FIG. 3 c, the floor panel is provided with a surface layer 31 of highpressure laminate, a core 30 of HDF and a balancing layer 32 of highpressure laminate. Also in this embodiment, the vertical locking meansconsists of a tongue groove 9 and a tongue 10 which are made from thecore 30 of the floor panel. The horizontal locking means consists of astrip 6 and the locking element 8, which are made of aluminum andmechanically attached to the core 30.

In the above cases, the joint systems are integrated with the core,i.e., formed or mounted at the factory, and at least part of the jointsystem is always made by cutting of the core 30 of the floor panel. Thelocking systems can be joined by angling, horizontal snapping orsnapping in an upwardly angled position.

FIGS. 4 a-4 c illustrate impregnation of joint edges 82, 83 according toprior-art technique, the machined joint being impregnated by animpregnating material 24 being applied sideways by spraying.

To facilitate the understanding, the floor panels are in all figuresillustrated with their surface layer directed upwards. In the actualproduction, the floor panels can however, be oriented with their frontside (upper side) directed downwards in the processing machinery and inthe subsequent impregnation.

In the prior-art type of impregnation, the floor panel is moved passed astationary spray nozzle 40. It is difficult to direct the jet ofimpregnating material 24 so that the edge of the jet is placedimmediately under the surface layer 31 in connection with the upperadjoining joint edges 16 with a view to making a material seal 20.

Even if the application can take place using protective plates 43 whichprotect the surface, it is difficult to provide an efficient protection.The strip 6 and the locking element 8 are in many cases an obstacle, andit is difficult to apply the impregnating material 24 with sufficientaccuracy and to obtain sufficiently deep penetration into the areaimmediately under the surface layer 31 at the upper adjoining jointedges 16. Thus the impregnating depth varies and is smaller immediatelyunder the surface layer and furthest away from the surface layer, as isevident from FIGS. 4 a-4 d.

FIGS. 5 a-5 c illustrate impregnation to make a material seal accordingto the invention. The impregnating material 24 is applied in a suitablefashion in band-shaped areas 44 on the core surface 33, before theremaining layers, i.e., the decorative and the wear layer are applied.The application can take place, for instance, by being sprayed, rolledon etc. conveniently first in the longitudinal direction L in zoneswhere the long sides of the floorboard are later to be formed.

Suitably one long side 4 of the core 30 is used as a guide surface whichis then also used as guide surface to facilitate the positioning inconnection with application of the surface layer 31, sawing up andmachining. In this way, it will be easier to ensure that the materialseal 20 is correctly positioned in relation to the completed joint edge.

FIG. 5 b illustrates the corresponding impregnation of the parts thatwill later constitute the short sides 5 of the floorboards. In thisimpregnation, the core is moved in the transverse direction Wperpendicular to the longitudinal direction L. Also in this case, oneshort side 5 of the core 30 can be used as guide surface in thesubsequent manufacture.

FIG. 5 c shows an enlargement of a portion that will constitute cornersof the floor panel and that will be fully impregnated parallel with thelong side to be as well as the short side to be. The parting lines 45indicate the saw cuts along the long side and the short side fordividing the board element into floorboards.

FIGS. 6 a-6 c illustrate in greater detail how the impregnation iscarried out and penetrates into the core and how the impregnating areais positioned relative to the connecting means to be, which areindicated by dashed lines in FIGS. 6 a and 6 b. FIG. 6 c shows the edgesof two floor panels which are made of the board element after this hasbeen cut into individual floorboards by sawing along the line 45.

FIG. 6 a shows how the impregnating material 24, when being applied bymeans of a spray nozzle 40, will penetrate into the core 30 from thecore surface 33 and towards the central portion of the core in order toform a material seal 20.

The penetration of the impregnating material 24 into the core 30 can befacilitated by establishing a vacuum on the underside of the core bymeans of a vacuum device 46. The vacuum device 46 may consist of, forinstance, a stationary vacuum table or moving vacuum bands. If the core30 is stationary during the application of the impregnating material 24,for instance moving spray nozzles 40 are used.

FIG. 6 b shows how the impregnating material 24 is positioned in thecore 30 of the board element 3 after application of the surface layer31. The impregnating material then constitutes a material seal 20. Theparting line 45 indicates the intended saw cut.

FIG. 6 c shows the joint edges 82, 83 of the floor panels 1, 1′ aftermachining. In order to simplify the illustration, the floor panel has amechanical joint along one side only. The material seal 20 will beexactly positioned along the two perpendicular sides and in the corner,and in the shown embodiment it is to be found in the upper joint edgeportions 80, 81.

A fiberboard-based core 30, e.g. HDF, is produced by ground wood fibersbeing mixed with a binder, such as melamine, after which a panel isformed by means of pressure and heat. Alternatively, the impregnatingmaterial 24 can be applied to the panel in connection with thisproduction, the application taking place within special portions whichwill later constitute joint portions in the floor panel.

FIGS. 7 a-7 d illustrate in detail the different production steps toproduce a material seal 20 in a mechanical joint system.

According to FIG. 7 a, impregnating material 24 is applied from the coresurface 33 in the portions 86, 87 (dashed) which in the completed floorpanel will constitute joint edge portions which are generally designated86 and 87 and in which the joint system 9, 10 is formed. A considerablepart of the upper joint edge portions 80, 81 is impregnated so as toform a material seal 20.

FIG. 7 b shows the floor element 3 with a surface layer 31, a balancinglayer 32 and a material seal 20 in the core 30 under the surface layer31. The Figure also shows the intended saw cut 45 and the contours ofthe final connecting means by dashed lines.

FIG. 7 c shows the edges of the floorboard 2, 2′ after sawing up. Thesawing tolerance does not affect the final position of the material seal20 closest to the joint edge. In the subsequent machining, no additionalequipment is required to provide a material seal 20 in the upper jointedge portions 80, 81 of a locking system since this material seal hasbeen provided even before the application of the different surfacelayers to the core 30.

FIG. 7 d illustrates the machined joint with a material seal 20immediately under the surface layer 31. HP designates a horizontal planeparallel with the surface layer of the panel. The joint edges of thefloor panel 1, 1′ are generally designated 82, 83 and can have anoptional joint system. In the shown embodiment, the joint edges areformed as a mechanical tongue-and-groove joint which can be locked byinward angling and snapping-in. VP designates a vertical plane (jointplane) which extends perpendicular to the horizontal plane HP at theupper joint edges 80, 81 closest to the surface layer. T indicates thethickness of the floor panel. The largest amount of impregnatingmaterial 20 is to be found in the upper joint edge portions 80, 81immediately under the wear layer 31, i.e. within the area which is mostcritical in the viewpoint of moisture. This concentration ofimpregnating material immediately under the wear layer 31 is obtained asa result of the impregnating material being caused to penetrate into thecore from the core surface during impregnation.

The material seal 20 in the upper joint edge portions 80, 81 is not onlyto be found in the core surface 31 closest to the surface layer 31between the vertical plane or joint plane VP and a lower plane at adistance P2 from the core surface 33, but also all the way in thehorizontal direction from the vertical plane VP to a plane at a distanceP1 from the vertical plane VP. This entire volume of the core 30 underthe core surface 33 is thus impregnated so as to form the material seal20. Such a location and extent of a material seal cannot be provided bymeans of the known impregnating methods in which impregnating material24 is applied to or sprayed onto the upper joint edges 84, 85 at thevertical plane VP when these upper joint edges are already provided witha surface layer 31 and machined to their final shape.

Since the impregnating material 24 penetrates from the core surface 33,the concentration of the impregnating material will be particularly highclosest to the core surface 33. In the normal case, the concentration ofimpregnating material decreases downwards from the core surface 33, asshown schematically in FIGS. 4 a-4 d.

The material seal 20 can, because of the expense, be limited to a partof the floor panel 1 where the intended connecting means are formed, andtherefore, in an exemplary embodiment, does not cover the entire coresurface 33.

A material seal 20 can be provided under the surface layer 31 in aconsiderable portion of the parts of the joint system. Regarding theextent of the material seal in the transverse direction, i.e.,transversely of the joint plane VP and along the horizontal plane HP, itcan be mentioned that P1 may exceed 0.2 times the floor thickness T and,without difficulty, may amount to 1 time the floor thickness T or more.In many embodiments, the distance P1 can be so great that all parts ofthe joint edge portion which contain parts of the connecting means ofthe floor panel are impregnated with the material seal 20.

The impregnating depth, i.e. the distance P2, can conveniently be0.1-0.3 times the floor thickness T. Preferably, the impregnating depthis such that at least upper parts of the connecting means will consistof impregnated core material.

The material seal 20 of the joint system is located in the core surface33 at the vertical plane VP and at a distance P1 from VP and that thesealing properties within this area are approximately equivalent orhomogeneous, i.e., the core surface 33 has been coated withapproximately the same amount of impregnating material 24 per unit ofvolume of core material 30. As illustrated in FIGS. 4 a-4 d, theconcentration of impregnating material decreases from the joint edge atthe vertical plane VP and inwards to the panel parallel with the surfacelayer 31 at the distance P1 and where the impregnating depth in thehorizontal plane will be smaller closest to the core surface 33 andgreater at a distance therefrom.

FIGS. 8 a-8 e illustrate a different embodiment of the invention. Inthis case, a groove 41 is formed in the core surface 33, for instance inthe area where the upper and inner part of the tongue 10 will later beformed. In the groove 41 a sealing material 50 is then applied, whichhas the property that after application it will have a solid form, bemoisture-proof, be elastically deformable and may be shaped by cutting.

As shown in FIG. 8 b, the core 30 with the groove 41 and the sealingmaterial 50 is then coated with a surface layer 31 and preferably alsowith a balancing layer 32 to form a floor element. Then the floorelement 3 is sawed up in floorboards by cutting along the line 45 and ismachined to floor panels 1, 1′ with joint systems. These floor panelsare shown in FIGS. 8 c-8 e, and the joining of the floor panelsaccording to this specific embodiment will be described in more detailbelow.

As described above, the groove 41 could also be formed in a floorelement or floor board which comprises a surface layer 31, 32 that isbonded to the core 30. This means that the groove 41 may be formed bothin the surface layer 31, 32 and in the core 30. This groove 41 could beimpregnated and/or provided with a sealing material 50. This methodoffers the advantages that a standard floor element could be used andimpregnation materials could be applied, which may be difficult to usein connection with gluing or lamination of the surface layer 31, 32 tothe core 30.

The sealing material 50 is formed to a joint seal 55, preferably bycutting by means of tools which are especially adapted to formelastically deformable synthetic materials.

As mentioned above, a large number of sealing materials that can be usedare available on the market. As a non-limiting example, materials havingthe following properties can be used.

A sealing compound based on acrylic plastics, elastomers of syntheticrubber, silicone rubber or the like, which have the properties that theycan be applied in the groove 41 as a compound by extrusion, that theycan adhere to the core material (optionally after applying a primerlayer thereto), that they have good heat resistance, that they aremoisture-proof, that they can resist detergents, and that afterapplication they can be cured or dried and change into a solid,elastically deformable form. The properties of the materials are bothsufficiently elastically deformable and preferably at the same time canbe machined rationally by means of cutting tools.

Different types of polyurethane-based hot-melt adhesives that areapplied by being heated and extruded can also be used to form the jointseal. When such materials solidify, they change into a solid,elastically deformable form. These materials can later be formed bycutting but also by using heated rolls or drag tools of a suitable form,which are moved along and in contact with the sealing material 50 toshape this to a suitable geometry.

Combinations of cutting rough machining and final forming by means ofhot scraping or rolling tools are also possible as is also a two-stepapplication, where the first application is carried out with a highlyliquid material that penetrates into the core, and where the subsequentsecond application takes place with a material which is more viscous andhas good adherence to the former material. It is also possible to usedifferent types of primer system to improve the adhesion of the jointsealing material to the floor panel.

Different materials, methods of application and methods of forming canbe used on opposite joint edges and respectively on the long side andthe short side for the purpose of optimizing function and cost.

FIG. 8 c shows the machined joint edge with a mechanical locking system9, 10, 6, 8, 12 and an elastically deformable joint seal 55. The jointseal 55 is compressed in connection with the laying of the floor panel.In this embodiment, which shows inward angling, the compression and thedeformation begin only when the locking element 8 is already in initialengagement with the locking groove 12 and when the tongue 10 is alreadyin engagement with the tongue groove 9. Both the vertical and horizontallocking functions in the mechanical locking system are thus active asthe compression proceeds. As a result, the compression in connectionwith laying can take place by applying an extremely small amount offorce, and the need for compression therefore does not render layingdifficult.

FIG. 8 d shows how two floor panels 1, 1′ are joined by snapping-in,where compression of the joint seal 55 can take place in the same manneras described above by interaction between a tongue groove 9 and a tongue10 and where lateral displacement along the joint plane has beenfacilitated and where a flexible strip 6, a locking element 8 and alocking groove 12 cooperate in the compression of the joint seal andtherefore will compress the joint seal in connection with snapping-in.

The joint seal 55 can be formed so that the compression can start whenthe guide part 11 of the locking element 8 engages the guide part 13 ofthe locking groove 12. This engagement can be facilitated if the guidepart 11 of the locking element is formed as a rounded or beveled part inthe upper portions of the locking element. The guiding as well as thecompression can also be facilitated if the locking groove 12 is formedwith a correspondingly rounded guide part 13 in the lower part of thelocking groove 12 closest to the joint edge.

In connection with laying, the joint seal 55 is pressed against anopposite cooperating joint surface 56 in the joint system. In theembodiment illustrated in FIGS. 8 a-8 e, this joint surface 56 has aninclination of 45 (to the horizontal plane HP of the panel. This isillustrated in FIG. 8 e. The pressure applied by the joint seal 55 willtherefore be uniformly distributed on the vertical 9, 10 and horizontal6, 8, 12 locking means of the joint system. This is advantageous sinceit is desirable to reduce the pressure both in connection with layingand in the locked position. Excessive pressure horizontally in thelocked position may result in the floor panels separating and the jointobtaining an undesired joint gap at the adjoining upper joint edges 16.Excessive vertical pressure in the locked position may result in risingof the joint edge portion 80 in the upper part of the tongue groove 9.

FIGS. 9 a-9 d show how the material seal 20 and the joint seal 55 can becombined to a moisture-proof locking system. In this case, a groove 41has been formed in the upper side of the core 30 after impregnation toform the material seal 20.

In this embodiment, both the tongue groove side 9 and the tongue side 10have been provided with sealing material 50 a, 50 b. The impregnatingmaterial 24 serves as binder and increases the strength of the core 30.In this embodiment (see FIG. 9 a) the impregnating material 24 has beenapplied in several areas on the core 30. These areas will constitute amaterial seal 20 and also a material reinforcement of the upper jointedge portions 80, 81. The impregnation can also provide an edgereinforcement 21 a, 21 b in the portions where the strip 6 is attachedand in an area 21 c in the core 30 adjacent to the locking groove 12where the locking groove 12 cooperates with the locking element 8.

FIG. 9 b shows how the sealing material 50 a, 50 b can be applied in thegroove 41. Once the core 30 has been provided with a surface layer 31and a balancing layer 32 (FIG. 9 c), the joint edge and the sealingmaterial 50 a, 50 b are formed to a joint seal 55 a, 55 b (FIG. 9 d). Asmentioned above in connection with FIG. 8 b, the sealing material couldbe provided in a groove that is made in both the surface layer 31, 32and in the core 30.

The strip 6 can be formed and fixed to the core 30 in different ways[for instance as shown and described in EP1061201 (Valinge Aluminium AB)or WO9824995 (Valinge Aluminium AB)], so that the mechanical lockingsystem for locking together the floor panels 1, 1′ in the vertical andhorizontal directions will comprise the tongue 10 and the tongue groove9; the joint seals 55 a and 55 b; the material seal 20; the strip 6 withits locking element 8; the edge-reinforced fixing parts 21 a, 21 b forthe strip 6; and an edge-reinforced locking surface 14 in the lockinggroove 12.

The floor panels 1, 1′ according to this embodiment will then have upperjoint edge portions 80, 81 which in the vertical plane VP have areinforced material seal 20 immediately under the surface layer 31 andjoint seals 55 a, 55 b in connection with the material seal 20. Thematerial seal 20 and the joint seals 55 a, 55 b together with themoisture-proof surface layer 31 counteract that moisture penetrates intothe core 30 and that moisture penetrates through the joint system. Thisresults in a moisture-proof floor. As mentioned above, the vertical 9,10 and horizontal 6, 8, 12 locking means should be designed in suchmanner that they can hold the elastically deformable joint seals 55 a,55 b compressed and elastically deformed during the life of the floorwithout the locking means being deformed. The tongue groove 9 is not tobe too deep in the horizontal direction and for the upper part or lip 15of the tongue groove can be rigid so as not to rise. Moreover thelocking element 8 and the strip 6 can be designed in such manner thatthey can resist the pressure applied by the joint seals 55 a, 55 bwithout the floor panels 1, 1′ separating while forming a visible jointgap adjacent to the upper joint edge portions 81, 82. The sealingmaterial 50 a, 50 b can also be selected so that during the entire lifeof the floor it exerts a pressure and prevents moisture migrationthrough the joint system.

As appears from FIG. 9 d, the core 30 is impregnated and reinforced inthe areas 21 a, 21 b and 21 c where the strip 6 is fixed and where thelocking element 8 locks against the locking groove 12. This can allowuse of less expensive core material 30, which can be of lower qualityand which by means of impregnation is reinforced to obtain greaterstrength in the critical areas. In this manner, high quality can becombined with low cost.

A plurality of variants of this moisture-proof locking system areconceivable. The joint seals 55 a, 55 b can be optionally arranged inthe joint system, but it is advantageous if the joint seal is arrangedinvisibly from the surface close to the surface layer 31. They can beoptionally arranged on the tongue groove side 9 or on the tongue side10, and they can, like in the embodiment shown, be found in both jointparts. Of course, several joint seals 55 can be arranged on each jointpart above and beside each other. Moreover, the contact surface betweenthe joint seal 55 and the opposite part in the joint system can bedesigned in an optional manner with geometries that are, for instance,toothed, triangular, semicircular and the like. Basically all the formsthat are normally used when designing sealing strips of elasticsynthetic material or rubber can be used.

Using vacuum technique as described in connection with the embodimentaccording to FIG. 6 b, the entire joint system from the surface layer 31to the balancing layer 32 can be provided with a material seal and edgereinforcement 20. This can increase the joint's strength and protectionagainst moisture, give the machined strip better flexibility, enablemachining to obtain smoother surfaces and enable a reduction of thefrictional forces when displacing one floor panel relative to another inthe locked position. It is also possible to impregnate wood fibers withplastic material in such manner that the wood fibers, together with theimpregnating material, will have such properties that they can be formedto a joint seal.

As described above, the sealing material 50 a, 50 b and/or 20 canalternatively be arranged in grooves which can also be made in the floorelement 3 or in the floorboard 2 before the connecting parts are made.The groove 41 can then be made in both the core 30 and the surface layer31.

Sealing material 50 a, 50 b can also be arranged at the edge of thefloorboard 2 or the floor panel 1 when the entire joint system or partsthereof have been made, and the final forming of the joint seal 55 a, 55b can also take place in a separate manufacturing step when the floorpanel 1 has already obtained its final shape.

By changing the angle of the pressure surfaces between the elasticallydeformable joint seals 55 a, 55 b, the direction and distribution of thecompression pressure can be adjusted between fully horizontal and fullyvertical direction. It is an advantage if the pressure surfaces are notperpendicular but are inclined in relation to the horizontal plane HP,so that the pressure is distributed with vertical and horizontalcomponents, so that the distribution of pressure is optimized inrelation to the possibilities, afforded by the combinations ofmaterials, of forming a rigid upper tongue groove part 15 and a stronghorizontal joint 6, 8, 12.

FIGS. 10 a-10 c illustrate in detail how compression can be achieved inconnection with inward angling. The active part 54 of the joint seal 55is formed with a convex outer part which starts to be compressed whenthe locking groove 12 engages the locking element 8. Such a position isshown in FIG. 10 b. In connection with the final downward angling andlocking, the final compression of the joint seal takes place against anopposite cooperating joint surface 56. The joint surface 56 can becoated with, for instance, wax or other similar materials after thejoint system has been formed. This can facilitate displacement along thejoint edge in the locked position and contribute to improving thefunctions of the material seal and the joint seal.

As is evident from FIG. 10 c, the joint system can have one of moreexpansion spaces 53 a, 53 b where the joint seal 55 can swell when beingpressed together. The joint seal 55 can thus be formed to have someexcess, and if the joint system has been formed with appropriateexpansion spaces 53 a, 55 b, the joint seal 55 can be formed with lowertolerance requirements and maintained function.

The material seal 20 in the upper joint edges has in this embodimentbeen made with a considerable depth from the core surface 33, whichmeans that the entire area from the upper parts of the joint seal 55 tothe core surface 33 is moisture-proof. In this embodiment, the majorpart of the joint edge portion between the tongue groove 9 and the coresurface 33 will constitute a material seal 20.

FIGS. 11 a-11 c illustrate different embodiments of the invention. FIG.11 a shows an embodiment according to the invention where the joint seal55 has been formed to minimize edge rising and separation of the jointedges. The contact surface of the joint seal 55 with the oppositecooperating joint surface 56 has a small angle to the plane of thepanel, which means that the major part of the compression force will bedirected approximately vertically in the direction of the arrow A. Thejoint edge above the tongue, however, is rigid and the risk of edgerising is small.

In the embodiment in FIG. 11 b, the elastically deformable joint seal 55a, 55 b is arranged immediately under the surface layer 31, whichsurface layer thus covers the joint seal. The upper part of the seal 55a, 55 b can constitute the material seal which prevents moisture frompenetrating into the core 31, while the lower parts of the seal 55 a, 55b can constitute the actual joint seal. The sealing 58 a, 58 b may alsocover part of the surface layer 31, 32 closest to the core.

The embodiment according to FIG. 11 c is characterized in that separatematerials 58 a, 58 b, which can constitute a material seal, are arrangedabove the elastically deformable joints seals 55 a, 55 b. These separatematerials 58 a, 58 b can also be used for the purpose of decoration bythe surface layer 31, for instance, being a beveled portion 60, so thatthe separate materials 58 a, 58 b will be visible in the joint. Such adecorative material may also be applied in a grove formed in the core 30and in the surface layer 31, 32 of the floorboard before the finalmachining of the edges of the floor panel.

The principles of sealing function also without the mechanical jointsystem if glue is applied between the tongue groove and the tongue 10.

FIG. 1 d shows an embodiment where one edge of a floor panel has amaterial seal 20 and the other edge a joint seal 55 a. The joint sealcovers the lower part of the surface layer 31. FIGS. 11 e and 11 f showhow the sealing material 55 a and 20 may be applied in groves 41 a and41 b, which are made in the floor board. The advantage of this method ismainly that the sealing material may be applied with great accuracy.Furthermore, application on the surface may be avoided, a considerableamount of impregnation could be applied, and the locking system may beformed to its final shape with great accuracy in a second machiningoperation where a reference surface such as 10 a may be used to positionthe floor board.

It is obvious that the application of a material seal and a joint sealcould be combined in several ways. Both sides could, for example, havematerial seal and joint seal, or only join seal or material seal, etc.In this embodiment, a considerable amount of impregnating material 20 isto be found in the upper joint edge portions, immediately under the wearlayer 31, i.e., within the area that is most critical in the viewpointof moisture. This concentration of impregnating material immediatelyunder the wear layer 31 is obtained as a result of the impregnatingmaterial being caused to penetrate into the core, from the groove 41 bclosest to the surface during impregnation. No protection of the surfaceclosest to the final edge is necessary, since the surface is protectedby the remaining part 31 a of the surface layer and since a considerableamount of impregnation material could be applied. The core part which isclosest to the surface could be impregnated to a horizontal depth ofabout 1 mm or more and the impregnation could be made with this depthover substantially the whole edge of the floor panel. The verticalconcentration of impregnating material 20 under the wear layer 31 ishigher at the joint surface than in the core. Naturally, the procedureabove, which was described with reference to the upper surface 33 of thefloor panel, may also be applied to the lower surface of the floorpanel.

FIG. 12 a shows an embodiment according to the invention where the core30 has been coated with three different surface layers having differentfunctions. The surface of the floor panel 1, 1′ comprises a transparent,hard and durable wear layer 34 of plastic material, an intermediatedecorative layer 35 of plastic film and a reinforcement layer 36 whichis made of an elastic material and which can be both moisture-proof andsound-absorbing. The decorative layer 35 of plastic film can be replacedwith decorative patterns which are printed directly on the underside ofthe transparent wear layer 34 or on the upper side of the elasticreinforcement layer 36. This embodiment could also be produced without aseal and may then constitute a floating floor panel with a wood basedcore such as HDF/MDF, a resilient surface and a mechanical lockingsystem for locking the floor panels horizontally and vertically at itslong and short sides through angling and/or snapping. The seal couldeven in this embodiment be applied in a grove that is formed in the coreand in the surface layer of the floor board.

The joint seal 55 a on the tongue side has an active part 54 in the formof a convex bulge which presses against the opposite elastic cooperatingjoint surface 56. The active part 54 of the joint seal 55 a has beenmade small, and this contributes to reducing the friction in connectionwith lateral displacement when the short sides of the floor panels areto be locked by snap action. Friction can also be reduced by the jointseals 55 a, 55 b being coated with different types of friction-reducingagents.

FIG. 12 b shows an embodiment with the same surface layer 31 as in FIG.12 a, but the joint seals 55 a, 55 b have been formed in the elastic anddeformable reinforcement layer 36 closest to the core 30. If the wearlayer 34 is harder than the reinforcement layer 36, on the one hand thedeformation of the joint seal 55 b will take place in the lower part 57of the joint seal closest to the core 30 and, on the other hand, nosignificant deformation of the wear layer 34 will take place. This canresult in a moisture-proof and sound-absorbing floor. Also in thisembodiment, the sealing means in the form of material seal and jointseal can be designed in many different ways as described above.

It is obvious that the above-described embodiments according to FIGS.6-12 can be combined. For instance, the sealing means according to FIGS.12 a and 12 b or 10 a and 10 b can be arranged in same joint system. Thestrip 6 can be made of aluminum etc.

FIG. 13 shows a floor panel 1 with a mechanical joint system on the longsides 4 a, 4 b and on the short sides 5 a, 5 b and with a joint seal 55a and 55 b on one short side 5 a and one long side 4 b. When the floorpanel 1 is connected with other similar floor panels 1′ on both longsides 4 a, 4 b and on both short sides 5 a, 5 b to form a floor, therewill be a joint seal on all sides.

If, besides, the joint edges have a material seal 20 according to theembodiments described above, the joint system of the floor panels willcounteract penetration of moisture into the joint system on all sides 4a, 4 b, 5 a, 5 b and in all corner portions 38 a, 38 b, 38 c, 38 d.

Linear machining of long sides and short sides makes it possible todesign the corner portions 38 a, 38 b, 38 c, 38 d with the same narrowtolerances as the sides 4 a, 4 b, 5 a, 5 b of the floor panels 1. Thejoint seal in the corners 38 a, 38 b, 38 c, 38 d can have an exact fit,and the angular displacements between the short sides 5 a, 5 b and thelong sides 4 a, 4 b as well as the deviations from parallelism betweenthe long sides 4 a, 4 b that may appear can be compensated for if it isensured that the possibility of the joint seals 55 a, 55 b beingdeformed when the floor panels have been joined, can exceed thesemanufacturing tolerances.

FIG. 14 a is a cross-sectional view of conventionally designed floorpanels 1, 1′, transversely of a joint along one long side of a woodenfloor. The floor panels 1, 1′ have a surface layer 31 of wood with amain direction of fibers parallel to the long side and a core 30 havinga different direction of fibers approximately perpendicular to the longside. The longitudinal side edges of the floor panel 1, 1′ have amechanical joint system 9, 10, 6, 8, 12. In moist surroundings, theupper joint edge portions 80, 81 swell transversely of the direction offibers (i.e. transversely of the joint between the neighboring floorpanels 1, 1′) more than does the core 30. This means that the floorpanels 1, 1′ along the long sides are pressed apart and that the strip 6is bent backwards. This involves a risk of the upper joint edge portions80, 81 or the cooperating locking surfaces 14, 18 being compressed ordamaged. As the floor panels 1, 1′ dry and shrink in winter (when therelative humidity falls), this may in turn result in a joint gap arisingbetween the upper joint edge portions 80, 81.

FIGS. 14 b-14 e show how it is possible to compensate for this risk ofjoint gaps arising by utilizing according to the invention an elasticcompensation seal 52 which is inserted into the horizontal locking means6, 8, 12 for counteracting the effects of swelling and shrinking of theupper joint edge portions 80, 81.

FIG. 14 b shows an embodiment of a floorboard 2′ which is suitable toform a joint system with a compensation seal according to the invention.The contour lines of the joint system to be have been indicated bydashed lines in FIG. 14 b. The surface layer 31, the core 30 and thebalancing layer 32 are laterally offset on both the tongue groove side 9and the tongue side 10 to minimize the waste when machining the jointedges. In the underside of the floorboard 2 a groove 40 is formed in thecore 30. An elastic material 51 is arranged and fixed in the groove 41by, for instance, extrusion or the like according to the previouslydescribed methods or alternatively by gluing or mechanical fixing by,for instance, pressing material into a groove.

In the subsequent machining, the elastic material 51 is removed orreshaped only partially and is formed to an elastic compensation seal 52which constitutes the active locking surface in the locking groove 12and which is operative in the horizontal direction D2. This isillustrated in FIG. 14 c.

As the joint edge portions 80, 81 swell, the elastic compensation seal52 will be compressed by its locking surface 14 pressing against thelocking surface 18 of the locking element 8. As a result, the mechanicallooking system can compensate for the great movements due to moisture inthe upper joint edge portions 80, 81 without the joint system beingdamaged or a visible joint gap appearing in winter when the floor hasdried and shrunk.

The problem with the upper joint edges swelling will be greater if thethickness WT of the surface layer 31 is considerable and if thisthickness is more than, for instance, 0.1 times the floor thickness T.

A joint system according to the above embodiment is especially suitablefor use together with underfloor heating and in surroundings where therelative humidity varies significantly during the year. The elasticlocking means or compensation seal 52 can be arranged optionally on thelocking element 8 (as in FIG. 14 d) or in the locking groove 12 (as inFIGS. 14 c and 14 e) or in both these parts, and it can be formed withmany different geometries having different angles and radii which canfacilitate inward angling and displacement. The elastic locking means orcompensation seal 52 can also be combined with a material seal 20 and ajoint seal 55 according to the previously described embodiments of theinvention.

FIG. 14 d illustrates an embodiment where the elastic locking means orcompensation seal 52 also serves as a joint seal, sealing againstmoisture. In this case, the seal 52 will, when compressed, also take upthe movements that are caused by swelling and shrinking of the upperjoint edge portions 80, 81. The compression and, thus, sealing capacityof the elastic seal 52 can thus increase when the floor panels arelocated in moist surroundings. In this case, there is a material seal 20which, however, has not been illustrated specifically in this Figure butwhich extends down to at least the upper parts of the connecting meansin the same way as shown in, for instance, FIG. 7 d.

FIG. 14 e illustrates an embodiment where the elastic compensation seal52 is compressed by a locking element 8 which is made of a materialother than that of the core 30. In this embodiment, the strip 6 and thelocking element 8 can be made of aluminum or some other convenientmetal. This construction has a flexibility which is greater than in thecase where the strip 6 is formed integrally with the core of the floorpanel. The invention can also be used in this embodiment. One of theadvantages of this embodiment is that the friction is low during lateraldisplacement in the locked position.

FIGS. 15 a-15 e illustrate a embodiment of a joint system with a jointseal 55 which has been arranged in the groove 41 in the core 30 adjacentto the upper and inner part of the tongue 10 and which has been formedusing a tool 70.

FIGS. 15 a and 15 b show the critical tolerance which lies in theposition of the tool 70 when forming, for instance, a groove 41 in thecore 30 or the board element relative to the vertical plane VP to be inthe floor panel 1′. The innermost position of the tool 70 is defined bya plane TP1. FIG. 15 b shows the outer position of the tool 70 which isdefined by a plane TP2 outside the vertical plane VP. As is evident fromthese two Figures, the contact surfaces of the joint seal 55 for contactwith the opposite cooperating joint portion 56 can be formed with greataccuracy although the manufacturing tolerance TP1-TP2 for the horizontalpositioning of the groove 41 relative to the joint edge to be at thevertical plane VP is fairly great and may exceed 0.2 times the floorthickness T. Using modern production equipment it is possible to managea horizontal lateral positioning with these tolerances in the entireproduction chain from production of the surface layer 31 and the boardelement 3 to the completed floor panel 1′. The positioning of the tool70 in the vertical direction is less critical since the tolerance mainlydepends on the thickness tolerances of the materials and since these asa rule are small in relation to the tolerances in connection with thelateral positioning.

In this embodiment, it is also possible to use the core surface 33 orthe surface of the surface layer 31 as reference surface. The groove 41and the sealing material 50, which is then formed into the joint seal55, can therefore be positioned with great accuracy in the verticaldirection. The active contact surfaces of the joint system and the jointseal 55 can therefore be made with very narrow manufacturing tolerances,which may be below 0.01 times the floor thickness T although theoriginal positioning of the sealing material 50 is effected withsignificantly lower tolerance requirements.

In an exemplary embodiment, the manufacturing tolerance between theactive part 54 of the joint seal and the upper adjoining joint edges 16can be significantly lower than the tolerance between another part ofthe joint seal which is not active, and the above-mentioned upperadjoining joint edge 16. This facilitates rational manufacture andenables high quality manufacture.

If the groove is formed in the core of the floor board and in thesurface layer 31, 32, the outer part of the tongue 10 could be formed inthe same machining step and this part of the tongue or some other partsof the floor board could be used as a reference surface when forming thelocking system and the seal 55. In this case, the vertical andhorizontal tolerances could be reduced to as little as 0.01 mm.

FIG. 15 c shows the joint seal 55 in its compressed state with expansionspaces 53 a and 53 b on both sides of the joint seal.

FIG. 15 d shows how the joint seal 55 can be formed to facilitatemachining of the surface layer 31 when this consists of a laminate. Whenmachining the upper joint edge 80 using a diamond cutting tool 71 whichoperates horizontally, i.e., perpendicular to the vertical plane VPaccording to the arrow R, great wear arises at the point 72 on thediamond cutting tool that works on the laminate wear layer 35 whichcontains aluminum oxide. In order to utilize a greater part of theactive surface of the diamond cutting tool, the tool is moved from itsstarting position 71, for example, step by step downwards in thedirection of the tongue 10. The starting position of the tool isindicated by the position 71 and its end position by the position 71′.If the joint seal 55 is located adjacent to the upper and inner part ofthe tongue 10 in the shown groove 41 and if its upper boundary UP islocated at a distance SD from the surface of the surface layer 31 thatexceeds, for instance, 0.2 times the floor thickness T, it is possibleto provide a joint seal 55 which is designed in such manner that themachining of the joint edge adjacent to and under the surface layer 31can be facilitated. This form and location of the joint seal 55 at adistance from the surface layer 31 also makes it possible to form, bysimple machining of the tongue 10 using the tool 73 (see FIG. 15 e) andthe opposite and cooperating joint portion 56 on the opposite jointedge, the locking system with radii and angles in a manner thatfacilitates a snapping-in and/or inward angling function of the lockingsystem.

FIGS. 16 a-16 e show locking systems that have a plurality of horizontallocking means. These locking systems can be used in connection withmoisture-proof locking systems but also merely as ordinary mechanicallocking systems to provide a locking system with great horizontalstrength. The basic principles can be used in locking systems which arejoined by inward angling or snapping-in and using strips 6 which areoptionally formed integrally with the core 30 or made of a separatematerial, such as aluminum, and then secured to the core.

Various combinations of the systems can be used on the long and shortsides. The locking elements 8 a, 8 b, 8 c and the locking grooves 12 a,12 b, 12 c can be made with different angles and radii of, for instance,wood, fiberboard-based materials, plastic materials and like panelmaterials with strips which are machined from the core or which consistof separate materials, and the locking elements can be designed forinstallation of the floor panels by angling or snapping-in.

The locking system according to FIG. 16 a has two strips 6 a and 6 b,two locking elements 8 a, 8 b and two locking grooves 12 a, 12 b. Thelocking element 8 a and the locking groove 12 a enable locking withgreat strength as well as good guiding in connection with, for example,inward angling. The locking element 8 b results above all great instrength and can significantly increase the horizontal locking force.The locking element can be designed so as to be operative when thehorizontal tensile force is so great that the upper joint edges begin tomove apart, for instance when a joint gap of 0.05 mm or 0.10 mm arises.

FIG. 16 b illustrates a locking system with three horizontal lockingmeans with the locking elements 8 a, 8 b, 8 c and the locking grooves 12a, 12 b, 12 c which can be made according to these basic principles.This embodiment consists of a locking means with good guiding capacity 8a, 12 a, and two locking means 8 b, 12 b and 8 c, 12 c which contributeto increasing the strength of the joint system in connection withhorizontal tension load. This joint system can hold together the jointedges during compression of the joint seal 55. Several locking elementscan be formed according to this method in the upper and lower parts ofthe tongue 10 and in the strip 6, and they can be adjusted to facilitateinward angling, snapping-in and guiding and to increase strength.

FIG. 16 c illustrates that a separate locking means 8 b, 12 b and/or 8c, 12 c, for example, can be used to limit separation in a joint systemwhere parts of the locking groove 12 a can consist of an elastic lockingmeans 52.

The locking systems according to FIGS. 16 a and 16 b are mainly intendedfor snapping-in but they can be adjusted, with minor changes of theangles and radii of the locking system, so as to be easier to angle.

FIG. 16 d shows a locking system with two horizontal locking means 8 a,12 a and 8 b, 12 b which are convenient for, e.g., the long side whichmay be laid by inward angling.

FIG. 16 e illustrates a locking system for e.g. the short side which maybe laid by snapping-in. The locking system according to FIG. 16 ediffers from that in FIG. 16 f among other things by the locking elementbeing smaller and having a greater inclination in relation to thesurface layer, the strip 6 a being longer and more flexible, the tonguegroove 9 being deeper, and the upper locking element 8 b having alocking surface which is more inclined in relation to the surface layer.

The locking grooves 12 b and 12 c can be made to have advanced forms bymeans of tools which need not necessarily rotate. FIG. 16 f illustratesmanufacture of the undercut groove 12 c in a joint system according FIG.16 b. The panel can, according to prior-art technique in metal working,be moved past a stationary grooving tool 74 which in this embodiment hasteeth 75 which operate perpendicular to the surface layer 31. When thefloor panel 1 moves in the direction of the arrow B, the floor panel canpass the grooving tool 74 which is inserted into the tongue groove 9 andthe teeth of which make the final forming of the undercut groove 12 withits locking surface. The major part of the tongue groove 9 is formed ina conventional manner using large rotating diamond cutting tools beforethe panel comes to such a position that the grooving tool 74 isoperative. In this manner, geometric shapes can be formed in the sameway as in extrusion of plastic or aluminum sections. This technique canalso be used to form the groove 41 in the core where the sealingmaterial is arranged.

FIGS. 17 a-17 d illustrate an enlargement of the corner portion 38 a ofthe floor panel, which has previously been illustrated in FIG. 13, andshow a joining of three floor panels 1, 1′ and 1″. Precisely the cornerportions constitute one of the critical parts in a moisture-proof floor.To counteract penetration of moisture into the joint system through thecorner, the joint seal 55 a, 55 b can be unbroken in at least one corner38 a according to FIG. 17 a. Moreover, the joint seal in the corner 38 dof the floor panel 1′ can be positioned and formed in such manner thatits active part 54 is not completely removed in connection with themachining of the different parts, specifically the tongue groove 9, ofthe joint system.

FIGS. 17 c and 17 d illustrate the joint system in a cross-sectionalview along the line C1-C2 in FIG. 17 b, i.e., the short side and thecorner portion 38 a of the panel 1′ are shown in an end view whereas thepanel 1 is shown in cross-section along this line C1-C2. In thisembodiment, the active part 54 of the joint seal is intact in the panel1′ at the outer end of the upper lip of the tongue groove 9 b. This isdue to the fact that the active part 54 is placed in a plane SA which ispositioned between the surface layer 31 and the upper part of the tonguegroove which in this case is an undercut groove 9 b. The active part 54of the joint seal can thus in this plane be in contact with an oppositecooperating joint surface 56 of the third floor panel 1″.

This embodiment makes the corner 38 a have an area SA where the sealingmaterial 55 a is positioned in one or more planes and where the jointseal 55 a is unbroken. There can thus be no gaps or hollows wheremoisture can penetrate from the surface and spread in the joint system.The exemplary embodiment of the floor panel has two corners 38 b, 38 dwhere the joint seals 55 a, 55 b are in unbroken contact with theopposite cooperating joint surface. The active part 54 of the joint seal55 is thus continuous along one entire long side and one entire shortside as well as in the corners between these long and short sides.

Hence, a system has been described, for forming a joint between twoadjoining edges 4 a, 4 b; 5 a, 5 b of floor panels 1, 1′ which have afiberboard core 30 and a surface layer 31 applied to the upper side 53of the core and consisting of at least one layer, and which at theiradjoining joint edges 82, 83 have connecting means 9, 10 for joining thefloor panels with each other in the vertical direction D1, the upperadjoining joint edges 16 of said floor panels 1, 1′ meeting in avertical joint plane VP. In the system, adjoining joint edge portions80, 81 of the floor panels 1, 1′ have a material seal 20 forcounteracting penetration of moisture into the cores 30 of the floorpanels from the joint edges 82, 83, said material seal 20 comprising animpregnation of the core 30 within said joint edge portions with amoisture-sealing agent and/or an agent counteracting or significantlyreducing swelling caused by moisture, from the upper side 33 of the core30 and at least a distance down towards the connecting means 9, 10.

In the system, the concentration of the moisture-sealing agent in thejoint edge portion may be higher at the core surface 33 than at adistance therefrom.

In the system, the impregnation of the core 30 may extend down to adepth P2 which is at least 0.1 times the thickness T of the floor panel.

In the system, the impregnation of the core 30 may extend down to adepth P2 which corresponds to at least half the distance between thesurface 33 of the core and the upper surfaces of the connecting means 9,10.

In the system, the impregnation may extend down to at least upper partsof the connecting means 9, 10.

In the system, the impregnation may extend from the joint plane VPinwards in the core 30 a distance P1 which is at least 0.1 times thethickness of the floor panel.

In the system, the impregnation may extend from the joint plane VPinwards in the core 30 a distance P1 which corresponds to at least halfthe width of the connecting means 9, 10, seen from the joint plane.

In the system, the impregnation may extend from the joint plane VPinwards in the core 30 a distance P1 which corresponds to the width ofapproximately the entire connecting means 9, 10, seen from the jointplane.

In the system, the core 3 within at least its joint edge portions may beimpregnated with a property-improving agent also from its underside.

In the system, the adjoining joint edges 82, 83 may also have connectingmeans 6, 8, 12 for joining the floor panels 1, 1′ with each other in thehorizontal direction HP perpendicular to the joint plane VP.

In the system, the core 30 within at least said joint edge portions maybe impregnated with a property-improving agent also from its undersideand at least a distance up towards the connecting means 9, 10, 6, 8, 12.

In the system, the impregnation may extend up to at least lower parts ofthe connecting means 6-10, 12, 14, 18.

In the system, the impregnating agent may be an agent improving themechanical properties of the core 30.

In the system, the impregnating agent may be an agent improving theelasticity properties of the core 30.

In the system, the core 30 may be impregnated over less than half thedistance between said opposite joint edge portions.

In the system, the core 13 may be impregnated within said joint edgeportions within which at least parts of the connecting means 6-10, 12,14, 18 are formed.

In the system, the connecting means 9, 10, 6, 8, 12 may be designed formechanical joining of neighboring floor panels 1, 1″ at a vertical jointplane VP both perpendicular to the same and perpendicular to the frontside of the floor panel.

In the system, the floor panels 1, 1′ may be quadrilateral and have alltheir opposite joint edge portions impregnated.

In the system, the entire core surface 33 at the joint edge portion ofthe corner portions 38 a-d may be impregnated.

In the system, the floor panels 1, 1′ may be quadrilateral and havemechanical joint systems 9, 10, 6, 8, 12 for vertical and horizontaljoining on all sides.

In the system, the connecting means 9, 10, 6-8-12 may be designed forjoining a floor panel 1 with a previously installed floor panel 1′ byinward angling and/or snapping-in to a locked position.

In the system, the connecting means 9, 10, 6, 8, 12 may comprise a lowerlip or locking strip 6 which may be formed integrally with the core andis included in the mechanical connecting means.

In the system, the lower lip or locking strip 6 is impregnated with anelasticity-improving agent.

In the system, the connecting means 9, 10, 6, 8, 12 may comprise anintegrated locking strip 6 which is made of a material other than thatof the core 30 and which is fixed to fixing elements 21 a, 21 b whichare formed along one of the opposite parallel joint edge portions ofeach floor panel.

In the system, the fixing elements 21 a, 21 b made in the core 30 forthe locking strip 6 may be impregnated with a property-improving agent.

In the system, the fixing elements 21 a, 21 b may be impregnated with astrength-increasing agent.

In the system, the connecting means 9, 10, 6, 8, 12 may be made bycutting.

In the system, the opposite joint edge portions 86, 87 of the floorpanels 1, 1′ may also have a joint seal 55 for counteracting penetrationof moisture along the joint surfaces of the joint edges betweenneighboring floor panels when joined, and that this joint seal 55 isformed at the joint edge portions 86, 87 and is made of an elasticsealing material 50, 50 a, 50 b, which is secured in at least one of thefloor panels 1, 1′ and which is compressed, when neighboring floorpanels are joined together.

In the system, the joint seal 55 may be formed of parts of theconnecting means 9, 10, 6, 8, 12 and/or portions of the floor panelparts above and/or below the connecting means.

In the system, the joint seal 55 may be designed in such manner that thetolerance within a floor panel and/or between different floor panels issmaller between the active part and the upper adjoining joint edges 16of the joint seal 55 than between another part of the joint seal 55 andsaid upper adjoining joint edges.

In the system, the joint seal 55 may be made of parts of the verticalconnecting means 9, 10 and/or portions of the floor panel partspositioned above the vertical connecting means.

In the system, the joint seal 55 may be made by machining of the elasticsealing material 50, 50 a, 50 b in connection with the designing of oneof the joint edges 82, 83.

In the system, the joint seal 55 may be made by machining of the elasticsealing material 50, 50 a, 50 b in connection with the designing of oneof the vertical connecting means 9, 10.

In the system, the active part 54 of the joint seal 56 may be designedin such manner that the compression is begun approximately when thelocking element 8 during inward angling comes into contact with theactive locking surface of the locking groove 12.

In the system, the active part 54 of the joint seal 56 may be designedin such manner that the compression is begun approximately when thelocking element 8 a during snapping-in comes into contact with theactive locking surface of the locking groove 12.

In the system, the floor panels may have a joint seal 56 with an activepart 54 on a long side and a short side, and that this active part 54 iscontinuous and covers all these long sides and short sides as well asthe corner portion between these long sides and short sides.

The system may further comprise an impact sound insulating layer 36 ofplastic between the core 30 and the decorative and wear layer 34. Also,in the system, the free surface portions of the impact sound insulatinglayer 36 facing the joint VP may be designed by cutting in connectionwith the designing of the joint edge and are formed as joint sealingmeans 55 a, 55 b which are compressed when neighboring floor panels 1,1′ are joined together.

In the system, the joint sealing means 55, 55 a, 55 b may be formed withcontact surfaces which are inclined to the upper side of the floorpanels 1, 1′ in the joined state.

The system may comprise more than one locking means 8 a, 8 b, 8 c forhorizontal joining of neighboring floor panels 1, 1′.

In the system, the locking means 8 a, 8 b, 8 c for horizontal joining,one may be placed on one side of the vertical joint plane VP and anotheron the other side of the vertical joint plane VP.

In the system, the locking means 8 a, 8 b, 8 c for horizontal joiningmay be arranged at different levels relative to the front side of thefloor panels 1, 1′.

Furthermore, a floor panel has been described, which has a fiberboardcore 30 and at least one surface layer 31 applied to the upper side ofthe core and which at least at two opposite parallel joint edge portions86, 87 has connecting means 9, 10 for joining of the floorboard in thevertical direction D1 with similar floorboards. In the floorboard, thecore 30 within at least said upper joint edge portions 80, 81 isimpregnated with a property-improving agent all the way from its upperside 33 and at least a distance down towards the connecting means 9, 10.

In the floor panel, the concentration of the property-improving agent inthe joint edge portion may be higher at the core surface 33 than at adistance therefrom.

In the floor panel, the impregnation may extend to a depth which is atleast 0.1 times the thickness of the floor panel.

In the floor panel, the impregnation of the core 30 may extend down to adepth P2 corresponding to at least half the distance between the surface33 of the core and the upper parts of the connecting means 9, 10.

In the floor panel, the impregnation may extend down to at least upperparts of the connecting means 9, 10.

In the floor panel, the impregnation may extend inwards from the jointplane VP in the core 30 a distance which is at least 0.1 times thethickness of the floor panel.

In the floor panel, the impregnation may extend inwards from the jointplane VP in the core 30 a distance corresponding to at least half thewidth of the connecting means 9, 10, seen from the joint plane VP.

In the floor panel, the impregnation extends inwards from the jointplane VP in the core 30 a distance P1 corresponding to at least half thewidth of the connecting means 9, 10, seen from the joint plane.

In the floor panel, the impregnation may extend down to at least upperparts of the connecting means 9, 10.

In the floor panel, the core 30 within at least said joint edge portionsmay be impregnated with a property-improving agent also from itsunderside and at least a distance up towards the connecting means 610,12, 14, 18.

In the floor panel, the adjoining joint edges 82, 83 may also haveconnecting means 6, 8, 12 for joining the floor panel 1 in thehorizontal direction HP with another similar floor panel 1′perpendicular to the joint plane VP.

In the floor panel, the impregnation may extend up to at least lowerparts of the connecting means 6-10, 12, 14, 18.

In the floor panel, the impregnating agent is an agent improving themechanical properties of the core 30.

In the floor panel, the impregnating agent may be an agent improving theelasticity properties of the core 30.

In the floor panel, the impregnating agent may be a moisture-sealingagent and/or an agent counteracting or significantly reducing swellingcaused by moisture and intended to form a material sealing means 20.

In the floor panel, the core 30 may be impregnated over less than halfthe distance between said opposite joint edge portions.

In the floor panel, the core 30 may be impregnated within said jointedge portions, within which at least part of the connecting means 6-10,12, 14, 18 are formed.

In the floor panel, the connecting means 6-10, 12, 14, 18 may be formedfor mechanical joining of the floor panel 1 with a neighboring similarfloor panel 1′ at a vertical joint plane VP both perpendicular to thesame and perpendicular to the front side of the floor panel.

The floor panel may be quadrilateral and have all its opposite jointedge portions impregnated.

In the floor panel, the connecting means 610, 12, 14, 18 may be formedfor joining a floor panel 1 with a previously installed floor panel 1′by inward angling and/or snapping-in to a locked position.

In the floor panel, the connecting means 6-10, 12, 14, 18 may comprise alower lip or locking strip 6 which is formed integrally with the core 30and is included in the mechanical connecting means 6-10, 12, 14, 18.

In the floor panel, the lower lip or locking strip 6 may be impregnatedwith an elasticity-improving agent.

In the floor panel, the connecting means 610, 12, 14, 18 may comprise anintegrated locking strip 6 which is made of a material other than thatof the core 30 and which is fixed to fixing elements 21 a, 21 b whichare formed along one of the opposite parallel joint edge portions of thefloor panel.

In the floor panel, the fixing elements 21 a, 21 b formed in the core 30and intended for the locking strip 6 may be impregnated with aproperty-improving agent.

In the floor panel, the fixing elements 21 a, 21 b may be impregnatedwith a strength-increasing agent.

In the floor panel, the connecting means 6-10, 12, 14, 18 may be made bycutting.

In the floor panel, parts of the connecting means 6-10, 12, 14, 18and/or adjoining portions of the core 30 within the upper parts of thejoint edge portions may be made of an elastic sealing material 50, 50 a,50 b, which is secured in the core 30 and designed by machining inconnection with the designing of the connecting means 6-10, 12, 14, 18and which is made to form a joint sealing means 55, 55 a, 55 b forcounteracting penetration of moisture between neighboring joined floorpanels 1, 1′.

In the floor panel, the joint seal 55 may be made of parts of theconnecting means 9, 10, 6, 8, 12 and/or portions of the floor panelparts positioned above and/or below the connecting means.

In the floor panel, the joint seal 55 may be designed in such mannerthat the tolerance within a floor panel and/or between different floorpanels is smaller between the active part of the joint seal 55 and upperadjoining joint edges 16 than between another part of the joint seal 55and said upper adjoining joint edges.

In the floor panel, the joint seal 55 may be made of parts of thevertical connecting means 9, 10 and/or portions of the floor panel partspositioned above the vertical connecting means.

In the floor panel, the joint seal 55 may be made by machining of theelastic sealing material 50, 50 a, 50 b in connection with the designingof one of the joint edges 82, 83.

In the floor panel, the joint seal 55 may be made by machining of theelastic sealing material 50, 50 a, 50 b in connection with the designingof one of the vertical connecting means 9, 10.

In the floor panel, the active part 54 of the joint seal 56 may bedesigned in such manner that the compression is begun approximately whenthe locking element 8, during inward angling, comes into contact withthe active locking surface of the locking groove 12 when the floor panelis joined with a similar floor panel.

In the floor panel, the active part 54 of the joint seal 56 may bedesigned in such manner that the compression is begun approximately whenthe locking element 8, during snapping-in, comes into contact with theactive locking surface of the locking groove 12 when the floor panel isjoined with a similar floor panel.

In the floor panel, there may be a joint seal 156 with an active part 54on a long side and a short side and that this active part 54 iscontinuous and covers the entire long sides and short sides as well asthe corner portion between said long sides and short sides.

The floor panel may comprise an impact sound insulating layer 36 ofplastic between the core 30 and the decorative and wear layer 34. Inthat floor panel, the free surface portions of the impact soundinsulating layer 36 facing the joint VP may be designed by cutting inconnection with the designing of the connecting means 6-10, 12, 14, 18and be made as joint sealing means 55 a, 55 b which are compressed, whenneighboring floor panels 1, 1′ are joined together.

Also described is a method of making a fiberboard core 30 which isintended for production of floorboards 2 or board elements 3 to bedivided into floorboards 2 which have opposite joint edge portions 86,87. The fiberboard core 30 in the exemplary method is impregnated withat least one property-improving agent within defined band-shaped areas44 which comprise joint edge portions 86, 87 to be of the floorboards 2.

In the method, the impregnation of the wood-based panel may take placefrom its front side to be.

In the method, the impregnation may be carried out in such manner thatthe concentration of the property-improving agent in the joint edgeportion is higher at the core surface 33 of the core than at a distancefrom the core surface.

In the method, the impregnation of the wood-based panel may take placefrom its rear side to be.

In the method, the impregnation may be carried out to a depthcorresponding to at least 0.1 times the panel thickness T.

In the method, the impregnation may be carried out at least to such adepth that parts of the connecting means 9, 10 to be of the floor panelswill be impregnated.

In the method, the impregnation may be carried out by applying a liquidimpregnating agent over the band-shaped areas 44.

In the method, the impregnation may take place with an agent improvingthe mechanical properties of the core 30.

In the method, the impregnation may take place with an agent improvingthe elasticity properties of the core 30.

In the method, the impregnation may take place with a moisture-sealingagent.

In the method, the impregnation may take place with a swelling-reducingagent.

In the method, the core 30 may be impregnated over less than half thedistance between said opposite joint edge portions.

In the method, grooves 41 may be formed in the panel within theband-shaped areas 44 to a depth on a level with the connecting means6-10, 12, 14, 18 to be of the floorboards, and an elastic sealingmaterial may be inserted in said grooves.

In the method, the elastic sealing material may be cast in said grooves41.

There is also described a method of producing a floorboard 2 or afloorboard element 3 which is intended to be divided into floorboards,which have opposite joint edge portions 86, 87, in which method afiberboard core 30 is coated with a surface layer 31 on its front sideand preferably also a balancing layer 32 on its rear side. Before thecoating with the surface layer 31 and a possible balancing layer 32, thefiberboard core 30 is impregnated with at least one property-improvingagent within defined band-shaped areas 44 comprising joint edge portions86, 87 to be of the floorboards.

In the method, the impregnation of the wood-based panel 30 may takeplace from its upper side to be.

In the method, the impregnation of the wood-based panel 30 may takeplace from its underside to be.

In the method, the impregnation may be carried out at least to such adepth that parts of connecting means 9, 10, 6-8-12 to be of thefloorboards will be impregnated.

In the method, the impregnation may be carried out by applying a liquidimpregnating agent over the band-shaped areas 44.

In the method, the impregnation may take place with an agent improvingthe mechanical properties of the core 30.

In the method, the impregnation may take place with an agent improvingthe elasticity properties of the core 30.

In the method, the impregnation may take place with a moisture-sealingagent and/or an agent counteracting or significantly reducing swellingcaused by moisture.

In the method, the core 30 may be impregnated over less than half thedistance between said opposite joint edge portions.

In the method, grooves 41 may be formed in the panel 30 within theband-shaped areas 44 to a depth on a level with the connecting means 9,10 to be of the floorboards and an elastic sealing material 50, 50 a, 50b may be inserted into said grooves.

There is also described a floorboard which is intended assemi-manufacture for producing a floor panel 1 and which has afiberboard core 30 and a surface layer 31 applied to the upper side 33of the core and which has at least two opposite parallel joint edgeportions 86, 87 which are intended for cutting to form connecting means9, 10 of the floor panel. The core 30 within at least said joint edgeportions 86, 87 is impregnated with a property-improving agent all theway from its upper side 33 and at least a distance down towards theconnecting means 9, 10.

In the floorboard, the concentration of the moisture-sealing agent inthe joint edge portion may be higher at the core surface 33 than at adistance therefrom.

In the floorboard, the impregnation may extend to a depth which is atleast 0.1 times the thickness of the floorboard.

In the floorboard, the impregnation of the core 30 may extend to a depthP2 which corresponds to at least half the distance between the surface33 of the core and the upper surfaces of the connecting means 9, 10.

In the floorboard, the impregnation may extend down to at least upperparts of the connecting means 6-10, 12, 14, 18 to be.

In the floorboard, the core 30 within at least said joint edge portionsmay be impregnated with a property-improving agent also from itsunderside and at least a distance up towards the connecting means 6-10,12, 14, 18.

In the floorboard, the impregnation may extend up to at least lowerparts of the connecting means 6-10, 12, 14, 18.

In the floorboard, the impregnating agent may be an agent improving themechanical properties of the core 30.

In the floorboard, the impregnating agent may be an agent improving theelasticity properties of the core 30.

In the floorboard, the impregnating agent may be a moisture-sealingagent and/or an agent counteracting or significantly reducing swellingcaused by moisture.

In the floorboard, the core 30 may be impregnated over less than halfthe distance between said opposite joint edge portions.

In the floorboard, the core 30 may be impregnated within said joint edgeportions, within which at least parts of the connecting means 6-10, 12,14, 18 of the floor panel are to be formed.

The floorboard may be quadrilateral and have all its opposite joint edgeportions impregnated.

In the floorboard, the joint edge portions on the upper side of thefloorboard may be impregnated with a moisture-sealing agent and/or anagent counteracting or significantly reducing swelling caused bymoisture.

In the floorboard, the joint edge portions on the underside of thefloorboard may be impregnated with a strength-increasing agent.

In the floorboard, the joint edge portions on the underside of thefloorboard may be impregnated with an elasticity-improving agent.

The floorboard may comprise an elastically deformable sealing material54, which is secured in the core in such positions thereof as, inmachining the floorboard to a floor panel, will form parts of theconnecting means 6-10, 12, 14, 18 of the floor panel and/or adjoiningportions of the core 30 of the floor panel within the upper parts of thejoint edge portions.

In the floorboard, the elastic joint sealing material 56 may be securedin the core 30 within areas which are intended to form a long side and ashort side of a floor panel to be and which are continuous along theentire long sides and short sides as well as a corner portion betweensaid long sides and short sides.

The floorboard may comprise an impact sound insulating layer 36 ofplastic between the core 30 and the decorative and wear layer 34.

According to this embodiment, a system is provided for forming a jointbetween two adjoining edges of floor panels which have a fiberboard coreand a surface layer applied to the upper side of the core and consistingof at least one layer, and which adjacent to their adjoining joint edgeportions have connecting means for joining the floor panels with eachother in the vertical direction and which meet in a vertical jointplane. According to this aspect of the invention, the adjoining jointsedge portions of the floor panels have a material seal for counteractingpenetration of moisture into the cores of the floor panels from thejoint plane. This material seal comprises an impregnation of the corewithin said joint edge portions with a moisture-sealing agent and/or anagent counteracting or significantly reducing swelling caused bymoisture all the way from the upper side of the core and at least adistance down towards the connecting means.

This impregnation may extend to a depth which is at least 0.1 times thethickness of the floor panel, seen from the upper side of the core. Morepreferably, the impregnation extends down to at least upper parts of theconnecting means of the floor panels. The extent of the impregnationseen from the joint plane and inwards in the core is preferably also atleast 0.1 times the thickness of the floor panel. More preferably, theimpregnation, seen from the joint plane, extends a distancecorresponding to at least half the width of the connecting means.

It is also preferred for the core to be impregnated from its undersideand at least a distance up towards the connecting means. Theimpregnation of the underside of the core can be effected using aproperty-improving agent, especially an agent which improves themechanical properties of the core.

In some connecting systems, it is possible to choose to improve thestrength and elasticity properties of the core for the core to bettersatisfy its function as starting material for mechanical connectingmeans.

Through this embodiment, the properties of the core are obtained withinthose parts of the floor panels which are most exposed to influence,i.e., the edge portions. This causes great economic advantages since theimpregnation of the core has been limited to precisely the portions thatneed be improved so as to obtain a floor having the desired propertiesas regards resistance to the influence of penetrating moisture. Theimpregnation of the core therefore preferably takes place to less thanhalf the distance between the opposite edges of the core. Theimpregnation is restricted to those parts of the edge portions withinwhich at least parts of the connecting means are formed.

As mentioned above, the embodiment is particularly usable in connectionwith systems which are based on mechanical joining of neighboring floorpanels, i.e., systems where the mechanical locking means join the floorpanels at a vertical joint plane both perpendicular thereto andperpendicular to the front side of the floor panels. The connectingmeans can particularly advantageously be designed for joining a floorpanel with a previously installed floor panel by inward angling and/orsnapping-in to a locked position.

When utilizing the embodiment for floor panels with mechanical lockingmeans, the connecting means may comprise a lower lip or locking stripwhich is formed integrally with the core. In such a case, it isparticularly advantageous, as mentioned above, to impregnate the lowerparts of the core with a property-improving agent, especially anelasticity-improving agent, so that this lower lip or locking stripobtains optimal properties for its intended function. Within the scopeof the invention, however, such a locking strip can also be made of adifferent material, for instance aluminum, and in that case the parts ofthe core which form the attachment for the separate locking strip canadvantageously be impregnated with such a property-improving agent inorder to further increase the core's capability of retaining theattached locking strip.

According to this embodiment, the problem of providing a material sealhas thus been solved by the core, and thus not the completed joint edge,being impregnated in the areas where the joint system will later beformed. The impregnating agent can be caused to penetrate so that theupper part of the core closest to the front side will be impregnated inan area where the joint edge will later be formed. Then the core iscoated with a surface layer on its front side and preferably also abalancing layer on its rear side. The board element or the floorboardwill thus contain parts where the core under the surface layer isimpregnated. The board element is sawn, where appropriate, intofloorboards having edge portions within which the core under the surfacelayer is impregnated. The edges of the floorboards are then machined andthe completed floor panels will have upper joint edge portions which areimpregnated.

An impregnating agent can be applied to the surface of the core and/orin the parts of the core under the surface using methods which do notrequire the impregnation to take place from the joint edge of themachined joint systems.

The main advantage of a joint system made according to thismanufacturing method is that the impregnating agent can be appliedwithout actually requiring tolerances. A further advantage is that theproduction line in the manufacture of board elements may have a highcapacity although the impregnation is carried out at a relatively lowspeed since the impregnation takes place in connection with theproduction of the large board elements which are later divided into aplurality of floorboards, and not in connection with the individual edgemachining of the floorboards. The impregnating material can also beallowed to penetrate into the core during a relatively long time.

Further advantages are that the method allows impregnating material tobe applied directly under the surface layer in areas adjacent to thecompleted joint edge, i.e., in the upper joint edge portion, and to havea significantly greater extent horizontally from the joint edge towardsthe floor panel compared with what can be achieved by impregnation fromthe joint edge of the floor panel after this has been machined formaking the connecting means. A further advantage is that all cornerswill have joint edge portions that are impregnated. Since the joint isformed after impregnation, any swelling in connection with theimpregnation will not affect the joint geometry, nor will there be anyimpregnating residues on the joint surfaces or on the surface layerclosest to the joint edge.

One more advantage is that the impregnating result can be checked bymeasuring the swelling of the core, the board element or the floorboardin portions where the joint edge will be made and in another, notimpregnated, part of the panel at a distance from this joint edge, forinstance closest to the central part of the floor panel to be.

The impregnating result can be ensured before the final machining of thefloor panels is made and this can result in a higher capacity and aconsiderable saving in costs in the form of a smaller amount of rejects.

This method of providing a material seal is suitable for allfiberboard-based core materials such as homogeneous wood, plywoodconsisting of a plurality of veneer layers, materials consisting of woodblocks glued together, fiberboard of the type HDF and MDF, particleboard, flake board (OSB) and the like. The method can also be used inother core materials which, for instance, do not contain wood fibers andwhich do not swell when exposed to moisture but where the intentionabove all is to obtain impregnation of certain parts with a view toproviding an edge reinforcement.

In principle, impregnating materials available on the market can be usedwhich contribute to increasing the protection against moisture in woodor fiberboard-based materials. However, it should preferably be possibleto apply them in liquid form, and they should have such properties as toallow surface layers to be applied to the core using such prior-artapplication methods as gluing, direct lamination, varnishing,calendaring or coating of plastic films or the like by extrusion,optionally in connection with grinding or application of primer layersand the like with a view to improving adhesion. As non-restrictiveexamples of usable impregnating materials, polyurethane, phenol andmelamine can be mentioned.

The impregnating liquid can be applied in different ways, for example,by spraying. Other methods, which are very difficult to use in thesystems that are used today for impregnating machined joint edges of acompleted floor panel, such as rolling, spreading, injecting and thelike, function in an excellent fashion in connection with the presentinvention. The penetration of impregnating agent into the core can befacilitated by applying heat, vacuum, pressure or the like, optionallyin combination with, e.g., grinding of the surface of the core beforeapplication of the impregnating agent. Grinding of the impregnated corecan also take place before applying the surface layer so as thus toremove any swollen surface parts before applying the surface layer.Vacuum and grinding of surface parts cannot be used when impregnation iscarried out from the joint edge, and several of the methods describedabove are also considerably more difficult to use when impregnating fromthe joint edge.

It is also possible to make grooves in the core in areas that will laterconstitute joint portions of the floor panel. The impregnating agent canthen be applied both from the surface of the core and from the edges ofthe groove. Different layers having different properties can also beapplied. Rolling or spreading is particularly advantageous in the caseswhere the impregnating agent contains substances which are notenvironment-friendly such as polyurethane (PUR) with isocyanate. Whenrolling on the impregnating agent, it is possible to use, within validlimits, up to 10 times more isocyanate than if application takes placeby spraying.

The impregnating method can also be used to reinforce the edge. Variouschemicals, such as those mentioned above, can be supplied in liquid formwhich after curing or solidification reinforce the wood fibers and givethe joint edge a higher compression, shearing or impact strength orelasticity. The preferred method is particularly suitable to provide amoisture-proof but also strong joint edge with the aid of e.g.thermosetting plastics such as melamine or phenol which as a rulerequire both heat and pressure to cure. Direct lamination of the surfacelayer in fact takes place at a high temperature and under high pressure,and in connection with this operation also the impregnating layer can becured. Hot-gluing of surface layers can also cause curing or drying.This method can be used in combination with moisture impregnation.

Different layers can also be produced by, for instance, a two-stepimpregnation where the first impregnating step is made with an agentthat penetrates deep under the surface of the core and gives increasedprotection against moisture, while the second impregnating step iscarried out with an agent which, for instance, has a different viscosityor other curing properties and which results in a strong joint edgeimmediately under the surface layer. In this way, for instancedirect-laminated floor panels can be produced which have reinforcedjoint edge portions, whose properties can be equivalent to or betterthan the considerably more expensive laminate floors which have asurface layer of high pressure laminate.

The embodiment above is intended to be used in order to change theproperties of the core by adding different materials before applicationof the surface layer in those parts of the core which will constitutethe joint edge portions of the floor panel.

While the present invention has been described by reference to theabove-mentioned embodiments, certain modifications and variations willbe evident to those of ordinary skill in the art. Therefore, the presentinvention is to be limited only by the scope and spirit of the appendedclaims.

1-9. (canceled)
 10. A floor panel, comprising a body having a core,wherein in said floor panel at least two opposite parallel joint edgeportions are provided with connectors for mechanical joining of thefloor panel in the horizontal direction with similar floor panels, saidconnectors having active locking surfaces for cooperation withcorresponding active locking surfaces of adjacent floor panels after thefloor panel has been joined therewith, the core having an upper surfacelayer, wherein a material seal of a resilient surface layer is disposedabove the upper surface layer of the core, the material seal consists ofplastic, and a surface layer is provided over the plastic.
 11. The floorpanel according to claim 10, further comprising a decorative layer. 12.The floor panel according to claim 10, wherein the surface layerdirectly contacts the plastic.
 13. The floor panel according to claim10, wherein the surface layer comprises an elastic material.
 14. Thefloor panel according to claim 10, wherein the resilient surface layercovers the upper surface layer of the core.
 15. The floor panelaccording to claim 10, wherein the plastic directly contacts the core.16. The floor panel according to claim 10, wherein the core is ofplastic material.
 17. The floor panel according to claim 10, wherein thecore is of wood fiber based material.
 18. The floor panel according toclaim 10, wherein the material seal is sound-reducing.
 19. The floorpanel according to claim 10, wherein the active locking surfaces areprovided in the core of the floor panel.
 20. The floor panel accordingto claim 10, wherein the connectors are configured for joining the floorpanel with a previously installed floor panel by inward angling.
 21. Thefloor panel according to claim 10, wherein the connectors are configuredfor joining the floor panel with a previously installed floor panel bysnapping-in to a locked position.
 22. A floor panel, comprising a bodyhaving a core, wherein in said floor panel at least two oppositeparallel joint edge portions are provided with connectors for mechanicaljoining of the floor panel in the horizontal direction with similarfloor panels, said connectors having active locking surfaces forcooperation with corresponding active locking surfaces of adjacent floorpanels after the floor panel has been joined therewith, the core havingan upper surface layer, wherein a material seal of a resilient surfacelayer is disposed above the upper surface layer of the core, thematerial seal is of plastic or linoleum, and a surface layer is providedover the plastic or the linoleum, the surface layer comprising anelastic material.
 23. The floor panel according to claim 22, wherein thesurface layer directly contacts the plastic or linoleum.
 24. The floorpanel according to claim 22, further comprising a decorative layer. 25.The floor panel according to claim 22, wherein the resilient surfacelayer covers the upper surface layer of the core.
 26. The floor panelaccording to claim 22, wherein the plastic or linoleum directly contactsthe core.
 27. The floor panel according to claim 22, wherein the core isof plastic material.
 28. The floor panel according to claim 22, whereinthe core is of wood fiber based material.
 29. The floor panel accordingto claim 22, wherein the material seal is sound-reducing.
 30. The floorpanel according to claim 22, wherein the active locking surfaces areprovided in the core of the floor panel.
 31. The floor panel accordingto claim 22, wherein the connectors are configured for joining the floorpanel with a previously installed floor panel by inward angling.
 32. Thefloor panel according to claim 22, wherein the connectors are configuredfor joining the floor panel with a previously installed floor panel bysnapping-in to a locked position.
 33. A floor panel, comprising a bodyhaving a core, wherein in said floor panel at least two oppositeparallel joint edge portions are provided with connectors for mechanicaljoining of the floor panel in the horizontal direction with similarfloor panels, said connectors having active locking surfaces forcooperation with corresponding active locking surfaces of adjacent floorpanels after the floor panel has been joined therewith, the core havingan upper surface layer, wherein a material seal of a resilient surfacelayer is disposed above the upper surface layer of the core, theresilient surface layer is of plastic or linoleum, and a surface layeris provided over the plastic or the linoleum.
 34. The floor panelaccording to claim 33, wherein the core is of plastic material.